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RESTORING PATTERN WITHOUT PROCESS IN LAKE RESTORATION: A LARGE-SCALE LITTORAL HABITAT ENHANCEMENT PROJECT ON LAKE TOHOPEKALIGA,
FLORIDA
By
ZACHARIAH C. WELCH
A DISSERTATION PRESENTED TO THE GRADUATE SCHOOL OF THE UNIVERSITY OF FLORIDA IN PARTIAL FULFILLMENT
OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY
UNIVERSITY OF FLORIDA
2009
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© Zachariah C. Welch
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ACKNOWLEDGMENTS
My experiences at the Florida Cooperative Research Unit, where I worked and
studied from 1999 to 2009, far exceeded my most optimistic expectations. My advisor,
Wiley Kitchens, kept me involved in a multitude of projects and tasks, inundating me
with anything and everything to do with research and academia. The environment he
and Franklin Percival provide for students and staff is unparalleled and directly
responsible for any accomplishments I have had over the last 10 years. Their unique
combination of humor, guidance, support, freedom, and pressure to perform beyond
your own expectations is truly a recipe for success. This is clearly evident by the caliber
of my peers, all of whom were instrumental at different stages of my graduate
experience. I would also like to thank Peter Frederick, whose undergraduate Wetlands
Ecology course I took so many years ago inspired me to pursue all areas wet and
muddy, introducing me to the greatest ecosystems on the planet.
I would be remiss not to thank the people who gave me the strength to tackle all of
life’s challenges with unwavering love, support and guidance: my parents, Curt and
Sandy, and my wife, Christa Zweig. My parents are ultimately responsible for all my
past and future successes, having instilled in me every good quality I possess. My wife,
whom I met during my graduate career, was an ear when I had to vent, a colleague
when I needed sound advice, a shoulder if I had to lean, and a refuge when I wanted to
get away. Thanks to all those who supported me through this wonderful experience.
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TABLE OF CONTENTS page
ACKNOWLEDGMENTS.............................................................................................................. 3
LIST OF TABLES ......................................................................................................................... 6
LIST OF FIGURES....................................................................................................................... 7
ABSTRACT ................................................................................................................................. 10
CHAPTER
1 INTRODUCTION................................................................................................................. 12
Ecosystem Restoration ...................................................................................................... 12 Lake Tohopekaliga.............................................................................................................. 15
Brief History .................................................................................................................. 17 Previous Studies .......................................................................................................... 19
Study Objectives and Methodology.................................................................................. 20 Pattern without Process .............................................................................................. 21 Mechanical Muck Removal Effects ........................................................................... 22 Effects of Environmental Disturbances on Muck Removal Project...................... 23
2 RESTORING LITTORAL VEGETATION PATTERNS WITHOUT KEY STRUCTURING PROCESSES ........................................................................................ 24
Introduction .......................................................................................................................... 24 Methods and Analyses ....................................................................................................... 28
Sample Locations ........................................................................................................ 30 Analyses ........................................................................................................................ 33
Pre/post restoration comparison ........................................................................ 33 Temporal analyses ............................................................................................... 37
Results .................................................................................................................................. 37 Hydrological Comparisons to Historical Record ..................................................... 37 Vegetation Response .................................................................................................. 40
Discussion ............................................................................................................................ 51 Historical Comparisons ............................................................................................... 51 Management Implications........................................................................................... 55
3 MUCK REMOVAL AS A TOOL FOR RESTORATION OF LITTORAL VEGETATION ON A SUBTROPICAL LAKE .................................................................. 60
Introduction .......................................................................................................................... 60 Methods and Analyses ....................................................................................................... 63
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Sample Locations ........................................................................................................ 64 Analyses ........................................................................................................................ 68
Pre/post-restoration comparison ........................................................................ 68 Temporal analyses ............................................................................................... 71
Results .................................................................................................................................. 71 Soils ............................................................................................................................... 71 Vegetation ..................................................................................................................... 72 Time Series................................................................................................................... 74 Community Changes................................................................................................... 77
Discussion ............................................................................................................................ 82 Muck Removal.............................................................................................................. 82 Management Implications........................................................................................... 85
4 HURRICANE EFFECTS ON A LARGE-SCALE LITTORAL HABITAT RESTORATION PROJECT............................................................................................... 89
Introduction .......................................................................................................................... 89 Methods ................................................................................................................................ 91 Results .................................................................................................................................. 93 Discussion .......................................................................................................................... 106
5 DISCUSSION .................................................................................................................... 113
Review ................................................................................................................................ 113 Management Implications................................................................................................ 117
APPENDIX
SPECIES LIST.......................................................................................................................... 121
LIST OF REFERENCES ......................................................................................................... 123
BIOGRAPHICAL SKETCH ..................................................................................................... 133
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LIST OF TABLES
Table page 2-1 Indicator values (0–100) of species in the six groups identified by the cluster
analysis. ........................................................................................................................... 42
3-1 Change in total dry biomass (g) from two pre- and two post-treatment sample periods of common species.......................................................................................... 74
3-2 Indicator values of species in the pre-enhancement period (Dec 2002, Jun 2003), with values ranging 0–100. .............................................................................. 78
3-3 Indicator values of species in the post-enhancement period (Dec 2007, Jun 2008), with values ranging 0–100. .............................................................................. 79
A Common species sampled over the period of study. ............................................. 121
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LIST OF FIGURES
Figure page 1-1 Location of Lake Tohopekaliga and East Lake Toho in relation to Lake
Okeechobee and the Kissimmee River. ..................................................................... 16
1-2 Daily mean water elevations in meters (NGVD) from January 1942 until Jun 2008.................................................................................................................................. 18
2-1 Location of study sites throughout the lake. .............................................................. 31
2-2 Monthly lake stage (Meters NGVD) for the pre-regulation period 1942–1964 (green), and post-regulation period 1965–2008 (red). ............................................. 39
2-3 Daily lake stage (Meters NGVD) for a pre-regulation (1944–1954) and post-regulation period (1992–2002). .................................................................................... 40
2-4 Frequency histogram displaying number of species per quadrat for all samples before and after restoration. ......................................................................... 41
2-5 Frequency histogram of species gain or loss by quadrat after restoration. .......... 41
2-6 CART model of pre-post restoration periods (9 groups, CV error = 0.36, Misclass rate = 17%). .................................................................................................... 44
2-7 NMS ordination of two pre- and two post-restoration sample periods. Approximate community boundaries based on cluster groupings were outlined on the ordination for ease of interpretation................................................ 46
2-8 NMS ordination of two pre- and two post-restoration sample periods. Approximate community boundaries based on cluster groupings were overlayed onto the ordination, and arrows show movement of samples through species space over time. ........................................................................... 47
2-9 MRT model of pre-post restoration periods (9 groups, CV error = 0.55). ............. 49
2-10 Changes in biomass of common species (in kilograms wet weight), including Nuphar advena and Nymphaea odorata grouped as lily pads. .............................. 51
3-1 Location of experimental study sites on a bathymetric map of Lake Toho (0–13 ft, or ~ 2 m). ............................................................................................................... 66
3-2 A boxplot of percent organic content in all soil cores from treatment and control plots, before (2002) and after (2008) the dry-down and muck removal project (before averaging sub-samples). .................................................................... 72
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3-3 Species richness by depth category and treatment, before and after restoration........................................................................................................................ 73
3-4 NMS ordinations of each site, with depth categories graphically separated. ....... 76
3-5 CART model of pre-treatment community distribution along the measured environmental gradients................................................................................................ 80
3-6 CART model of post-treatment community distribution along the measured environmental gradients................................................................................................ 82
4-1 Lake stages (meters above sea level NGVD) following the managed dry down in summer of 2004............................................................................................... 92
4-2 Initial relative abundances of dominant species in scraped experimental plots. ................................................................................................................................. 94
4-3 Initial relative abundances of dominant species in control (unscraped) experimental plots. ......................................................................................................... 95
4-4 Initial species compositions of dominant species in scraped sections of lake-wide study sites. ............................................................................................................. 96
4-5 Average wet biomass per site (kg) of all species in the shallow, scraped (gray) and deeper water, unscraped (black) sections of the lake-wide study sites. ................................................................................................................................. 97
4-6 Average wet biomass per site of A) P. acuminatum (grams) in the shallow, scraped (gray) and deeper water, unscraped (black) sections of the lake-wide study sites, and B) P. geminatum (kilograms). ................................................ 98
4-7 Average dry biomass per site (g) of P. acuminatum in control (gray) and treated (black) sections of experimental plots. .......................................................... 99
4-8 Number of empty samples in experimental plots (gray and black) and lake-wide study sites. ........................................................................................................... 101
4-9 Average daily lake stage (meters NGVD) with horizontal dashed lines representing normal maximum and minimum lake stages. ................................... 102
4-10 Average wet biomass (g) of the five dominant species at the end of the study in the lake-wide sites. .................................................................................................. 103
4-11 Average dry biomass (g) of the five dominant species at the end of the study in the A) treated plots and B) control plots of the experimental study sites........ 104
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4-12 Average number of Vallisneria plants (per m2) across all samples, including experimental and lake-wide study sites.................................................................... 105
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Abstract of Dissertation Presented to the Graduate School of the University of Florida in Partial Fulfillment of the Requirements for the Degree of Doctor of Philosophy
RESTORING PATTERN WITHOUT PROCESS IN LAKE RESTORATION: A LARGE-SCALE LITTORAL HABITAT MODIFICATION PROJECT ON LAKE TOHOPEKALIGA,
FLORIDA
By
Zachariah C. Welch
December 2009
Chair: Wiley M. Kitchens Major: Interdisciplinary Ecology
Muck removal is an extreme habitat restoration technique, where heavy machinery
is used to remove dense vegetation and accumulated organic material from lake
shorelines. This approach is used to combat accelerated plant growth and subsequent
litter deposition, following decades of altered hydrologic schedules, elevated nutrient
levels, and exotic species introductions. This study explored the efficacy of the
technique, using results from the largest muck-removal application to date.
Vegetation communities were monitored from 2002 to 2008, including two years
prior to restoration and four years after. Before muck removal, Pontederia cordata
represented the dominant community in the zone of annual water level fluctuation, as
compared to Panicum repens, which was dominant in the 1950’s. Four years after
muck removal, P. repens had expanded slightly from its pre-restoration levels, but the
dominant species in treated areas was Vallisneria americana. This submersed species
had no record of ever being prevalent in the system, and represented a novel
community.
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Muck removal effects were short-lived in the shallowest areas of the littoral zone,
with sites < 0.75 meters in depth recovering to pre-treatment levels within 3–4 years of
reflooding. Deeper sites (> 1.0 meter) generally had the largest impacts, with entirely
new communities established within three years of treatment. These results suggest
that future projects focus on deeper-water emergent communities, as dense vegetation
may quickly recolonize shallow shorelines.
There was concern among managers that hurricanes passing over the lake
immediately following muck removal dramatically altered the outcome of the project, but
this study found otherwise. While corresponding high water events undoubtedly
delayed recovery in treated areas, the compositions of early colonizers were not
changed. The same compositions found just prior to hurricane passage were found the
following growing season, and the eventually-dominant communities did not appear until
nearly two years after the storm events. These results suggest that initial water levels
were less important in determining restored community types than the longer-term
hydroperiods within treated areas.
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CHAPTER 1 INTRODUCTION
Ecosystem Restoration
Ecosystem restoration has become increasingly important over the last decade
(Suding et al. 2004) and its application increasingly complex. In the simplest case
restoration and degradation can be depicted as linear processes traveling in opposite
directions along parallel pathways (Dobson et al. 1997), with recovery occurring when
the appropriate stressor is removed from the system. Restoration efforts usually begin
by re-establishing historical structure or species mix (pattern), and/or the environmental
conditions (processes) that permit a site to become self sustaining (Parker 1997). For
example, prairie restoration may begin with re-introducing fire to eliminate woody
species encroachment (Doren and Whiteaker 1990). This "applied succession"
approach (Niering 1987), where re-establishing key structuring processes produces a
desired pattern through self-organization (Mitsch and Wilson 1996) works well when a
single constraint exists (Suding et al. 2004).
The degree to which restoration is possible, however, is generally limited by the
severity of degradation and the effort that can be applied (National Research Council
1992). In reality, degradation is not a linear process and involves multiple paths of
change in species abundances and ecosystem function (Zedler 2000). As ecosystems
move through multiple states of degradation (Hobbs and Norton 1996), there are
disturbance thresholds that may be crossed, making reversal much more difficult, if not
impossible (Whisenant 1999, Lindig-Cisneros et al. 2003). Recent studies have shown
that feedbacks can develop between novel communities and degraded environmental
conditions that result in resilience to restorative change, even after key structuring
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processes (fire, nutrients, hydrology) have been restored (Bakker and Berendse 1999,
Zedler 2000, Suding et al. 2004). For example, fires may be ineffective at restoring
prairie grass communities if invading woody species impact burn efficacy, resulting in a
novel composition (Anderson et al. 2000). Similarly, overgrazing in semi-arid systems
and subsequent shrub encroachment can lead to changes in soil characteristics and
water availability that cannot be reversed by simply easing grazing pressure (van de
Koppel et al. 1997).
To further complicate matters, there are many cases where historical structuring
processes may no longer be restorable; natural disturbances like fires and floods are
often suppressed or eliminated entirely from the system. Prescribed burns are
increasingly difficult to conduct near urban areas, and historical flood levels in urbanized
watersheds cannot be achieved without property losses. Essentially, the historical
range of environmental variability in many ecosystems no longer exists, and restoring
these key structuring processes may no longer be an option (Seastedt et al. 2008).
Lakes and wetlands near urban areas are prime examples of such ecosystems,
where a permanent loss of historical water level fluctuations and their crucial role in
maintaining function and pattern is often accompanied by invasive or exotic species
introductions and nutrient pollution (Havens et al. 1996). How can restoration succeed
under such novel conditions? One approach is to find surrogates for lost
processes; Infrequent, catastrophic fires in forests have been replaced by clear-cut
logging (Hunter 1993) and spring-grazing by cattle has replaced frequent fires in prairie
grasslands (Seastedt et al. 2008). In lakes and wetlands, managers have long used
drawdowns in place of natural droughts, but, like prescribed burning, this becomes
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increasingly difficult in large systems or where recreational activities are interrupted.
Additionally, new communities established under higher nutrient loads and stabilized
water levels can reduce the efficacy of infrequent drawdowns (Moyer et al. 1989),
maintaining dominance over more desirable communities even after drawdowns. In
some cases, heavy machinery has been used to speed up organic sediment and
biomass removal during drawdowns in an attempt to restore desired plant communities
and substrate qualities to degraded systems (Moyer et al. 1995, Hoyer et al. 2008).
In warm-water, shallow lake systems, decades of excessive vegetation growth
under eutrophic and stabilized water conditions can lead to thick, organic substrates
and the establishment of highly competitive plant monocultures. Dense vegetative
growth can impede navigation, alter fish communities (Killgore et al. 1989) and foraging
efficiency (Diehl 1992), and combined with exotic species introductions can have
dramatic impacts on shallow, warm-water lakes (Hoyer and Canfield 1997). As with
many aquatic ecosystems, the disturbance regime (flood/drought cycle), species pool,
and geochemical conditions of these systems are or will soon be outside of their
historical ranges. To combat these effects, an aggressive restoration approach has
been implemented in several such systems across Florida.
This technique, hereafter referred to as muck removal, involves exposing parts of
the littoral zone with drawdowns, removing accumulated organic material, and
regulating initial plant establishment with selective herbicide treatments. The goal of
these projects is ultimately to improve fish spawning habitat, recreational access, and
overall water quality by removing dense littoral vegetation and associated organic
substrates, and reducing the abundance of rapid litter-producing species like cattail
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(Typha spp.) and pickerelweed (Pontederia cordata) in the near-shore littoral zones
(Hoyer et al. 2008).
While several studies of this technique have focused on sport fish response
(Moyer et al. 1995, Allen et al. 2003), little information exists about actual habitat
changes following these restoration activities (but see Moyer et al. 1987, Tugend and
Allen 2004). These types of extreme management approaches represent the
challenges facing restoration ecology in the future, specifically where historical
structuring processes cannot be restored. Many inland waterbodies are or will soon be
facing issues like those of many Florida lakes, and it serves as an excellent example of
intensifying management efforts to replace natural processes in aquatic system
restoration. This paper will focus on the largest application of this muck removal
application to date, which took place on a central Florida lake, Lake Tohopekaliga.
Lake Tohopekaliga
Lake Tohopekaliga (hereafter referred to as Lake Toho) is one of several large
lakes located in the upper Kissimmee River basin, collectively draining thousands of
square kilometers into the Kissimmee River and ultimately Lake Okeechobee (Figure 1-
1). Lake Toho and an adjacent sister lake, East Lake Toho, are the northernmost lakes
in the basin, lying between the Orlando and Mount Dora Ridges in the Osceola Plain.
This plain consists mainly of poorly drained, clayey sediments with poor groundwater
recharge, having over 73 lakes at least 3.2 ha in size (HDR Engineering 1989). Most of
the lakes in this region were formed from solution activities and are precipitation driven.
Lake Toho is the largest lake in the Osceola Plain, covering an area of 8,176 ha
with an average depth of 2.1 m at maximum pool (16.75 m NGVD) (HDR Engineering
1989, Remetrix LLC 2000). The immediate watershed is 340 km2, though an additional
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686 km2 of East Lake Toho watershed ultimately drains into Lake Toho through canal
C-31 (HDR Engineering 1989). Nearly half of these 1334 km2 are drained primarily by
two main stream systems: Shingle Creek, located north of Lake Toho and flowing
directly into the northwest side of the lake; and Boggy Creek, northeast of Lake Toho
and flowing into East Lake Toho. Depending on precipitation and the operation of
control structures on C-31 (drainage canal from East Lake Toho to Lake Toho) either
Shingle Creek or the discharge from East Lake Toho can account for as much as 50%
of the inflow to Lake Toho (Fan and Lin 1984, HDR Engineering 1989).
Lake Okeechobee
Orange County
Osceola County
Kissimmee River
FloridaEast Lake Toho
Lake Tohopekaliga
N
EW
S
5km
Lake Okeechobee
Orange County
Osceola County
Kissimmee River
FloridaEast Lake Toho
Lake Tohopekaliga
N
EW
S
5km5km
Figure 1-1. Location of Lake Tohopekaliga and East Lake Toho in relation to Lake
Okeechobee and the Kissimmee River.
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Brief History
Historically, much of the watershed in the upper Kissimmee River basin was
dominated by wetlands, with lakes bordered and interconnected by large wet prairie
sloughs, including the connection of Lake Toho and East Lake Toho by Fennel and
Cross Prairies (HDR Engineering 1989). This network of waterbodies flowed south
primarily through the Kissimmee River, virtually connecting waters of interior central
Florida to Lake Okeechobee.
As early as the 1850s, pioneers began to modify the hydrology of the system and
by 1884 a navigable waterway was opened from Kissimmee all the way to Fort Myers
(HDR Engineering 1989). After the Florida Legislature passed the General Drainage
Act in 1913 (Chap. 298, FS), a reported 108 km (67 mi) of canals were dug throughout
the Shingle and Boggy Creek Basins (Blackman 1973). Catastrophic hurricanes in the
1940s sparked several flood control projects with major changes occurring in the upper
Kissimmee River basin by 1957. These projects were designed to construct levees and
control structures on the south ends of the larger lakes, to improve channels to
downstream lakes, and for regulation of upper lake levels within a 0.6–1.2 m range
(HDR Engineering 1989, U.S. Army Corps of Engineers 1956). Water control structures
and canals regulating flows to and from Lake Toho were completed in 1964 (Blake
1980), marking the end of natural water level fluctuations. This resulted in a stage
reduction from at least 3.2 m to a maximum of 1.1 m (Wegener et al. 1973). Figure 1-2
shows the sharp contrast between the dynamic, astatic condition prior to impoundment
in 1964 and the stabilization that has occurred since.
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14.50
15.00
15.50
16.00
16.50
17.00
17.50
18.00
6/1/40 5/30/1950 5/27/1960 5/25/1970 5/22/1980 5/20/1990 5/17/2000
Regulation Begins
Dai
ly E
leva
tion
(met
ers
NG
VD)
1945 1955 1965 1975 1985 1995 2005
16.0
17.0
18.0
15.0
Figure 1-2. Daily mean water elevations in meters (NGVD) from January 1942 until Jun
2008. The dashed gray vertical line represents the approximate time of impoundment in 1964 while the dashed circles indicate managed drawdowns. The natural drought in 1962 and flood in 1960 were the lowest and highest on record at that point.
Sewage treatment plants began pumping effluent into the Shingle and Boggy
Creek basins as early as the 1940s, and by 1986 an estimated 113 million liters per day
(30 million gallons) were being discharged into these systems (Wegener et al. 1973).
Though water quality problems were recognized and attributed to these plants in 1969
(Wegener 1969), discharges were not completely eliminated until 1988. By that point
nutrient loading and water level stabilization had noticeably affected littoral habitats,
water qualities, and fish populations (Moyer et al. 1989). Mean lake phosphorous (total)
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levels dropped 85% from 1980 to the mid 1990’s (0.82–0.11 mg/L), while total nitrogen
dropped 50% (2.69–1.30 mg/L) (Williams 2001).
Previous Studies
In 1969, the Florida Fish and Wildlife Conservation Commission (FFWCC)
recommended that all effluent discharges into Lake Toho be stopped and that a
managed drawdown be performed in hopes of sparking seed germination and
recolonization of desired species (Wegener 1969). The first managed drawdown of the
lake took place in 1971, lowering the water from a high pool stage of 16.75 m to 14.65
m (55–48 ft) NGVD (National Geodetic Vertical Datum). The lake was held there for
nearly six months and drought conditions further extended the refilling to high pool
stage until March of 1973. During this period the FFWCC conducted studies on fish,
invertebrates, vegetation, soils, algae, and water chemistry (Wegener et al. 1973).
Vegetation studies consisted of fixed sampling along line transects established
perpendicular to the shore, ranging from above high pool stage to the lakeward extent
of emergent vegetation. Frequencies of occurrence of species were recorded based on
a form of line intercept method using a five-pointed rake (Sincock et al. 1957). At that
time the only vegetation considered a nuisance was water hyacinth (Eichhornia
crassipes) and the overall expansion of littoral communities into the lake by 16% was
hailed as a success (Wegener and Williams 1974).
Another drawdown was performed in 1979 based on the successes of the
previous effort. Sport-fish populations increased to a maximum by 1982 and then
gradually declined to the lowest level since 1972 (Moyer et al. 1989). Based on these
data it was assumed the habitat had degraded substantially and would no longer
support maximum fish densities. No vegetation studies were conducted.
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In 1987, the discharge of effluent to the lake was almost eliminated and another
drawdown was performed. Contrary to the others, which were implemented to increase
the density and area of the littoral zone in general, the purpose of this project was to
eliminate dense, monocultural stands of vegetation (Polygonum spp. and Pontederia
cordata) that had formed an organic barrier from accumulated organic matter; isolating
many shallow areas of littoral zone to the point of blocking access of sport fish to
important spawning grounds (Moyer et al. 1989).
The goal of the 1987 dry down was to reestablish native grasses in place of these
dense, monocultural stands of unwanted vegetation. This marked the first mechanical
muck-removal project, scraping approximately 172,000 m3 of muck and vegetation from
various sections of shorelines. After just two years, however, line transect studies
established in 1986 showed an almost complete rebound of the vegetation targeted for
removal (Pontederia cordata), though several grass species increased in frequency as
well (Moyer et al. 1989).
A natural drought in 1991 gave lake managers another opportunity to remove
some of the unwanted vegetation and two removal experiments were performed, one
involving mowing the vegetation to a maximum height of 15 cm and the other, uprooting
and removing it. It was found that Pontederia rebounded in both treatments, though at
a slower rate after uprooting. Herbicide applications were also made in hopes of
minimizing the regrowth of Pontederia, but were only effective at slowing regrowth.
Study Objectives and Methodology
Muck removal projects can provide important information to managers and
restoration practitioners beyond the specific effects of individual projects. For one, they
are prime examples of “aquatic gardening”, or using increased external inputs/efforts to
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maintain or establish a desired pattern in a system, rather than restoring the key
structuring processes that may have produced that pattern originally (Mitsch and Wilson
1996). Large-scale applications also provide an opportunity to implement adaptive
management strategies, comparing pre- and post-restoration communities and testing
the efficacy of new management activities before applying to other systems.
Additionally, they provide an opportunity to study how aggressive management
techniques perform at large scales; i.e. how well the results conform to predicted
effects, and what might impact such outcomes. These are all important issues in
restoration applications, and the following chapters of this paper will attempt to address
them. These issues can be broken down into three primary questions, which are further
discussed throughout the document:
• Can aggressive, intensive management efforts re-establish desirable littoral vegetation patterns without the structuring processes (hydrology, nutrients) that maintained those patterns historically?
• By comparing pre- and post-restoration littoral vegetation communities, what are the effects of this technique and how might these results be incorporated into future applications?
• How well did vegetation responses to a large-scale restoration project follow manager’s predictions? Did environmental disturbances immediately following muck removal lead to unexpected results? What factors might need to be addressed before implementing expensive, intense restoration efforts?
Several study sites and sample designs were implemented to address these
questions, and an outline of the differences is included below to aid interpretation.
Pattern without Process
The ability to re-establish vegetation patterns without historical structuring
processes (Chapter 2) was studied on a variety of shorelines throughout the lake.
Sampling occurred within the entire emergent littoral zone at these sites, both before
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and after the project was initiated. The primary difference from the sites addressed in
Chapter 3 is that sampling was conducted in both shallow and deeper sections of the
emergent littoral zone, not all of which were mechanically scraped. Substrate quality
and water levels limited the extent to which heavy machinery could drive onto the
exposed lake bottom, which essentially restricted muck removal to an elevation of
roughly 135 cm in water depth at maximum lake stage. Emergent vegetation extended
tens or even hundreds of meters beyond those depths, to roughly 200 cm in depth at full
pool. Thus, some of the samples were located in shallower, scraped sections of
shoreline, and others were located in deeper, unscraped sections of shoreline. These
scraped/unscraped designations may be confused with treatment and control plots that
are addressed in Chapter 3. The important distinction is that the lake-wide study sites
were all mechanically scraped, unless they occurred in areas too deep for muck
removal. Thus, there are no “control” samples in these sites, only scraped (shallower)
and unscraped (deeper).
Mechanical Muck Removal Effects
The pre- and post-restoration comparison of vegetation communities, or
restoration effects, were derived from experimental study sites located along specific
sections of shoreline that were on similar slopes and dominated by similar communities.
Sampling within these sites was restricted to only those depths that mechanical removal
could occur, and did not include the deeper-water, unscraped sections of emergent
littoral zone that are included in Chapter 2.
Throughout Chapters 3 and 4, these study areas will be referred to as
experimental sites, which contained both control and treatment plots. These study
areas had sections of shoreline specifically delineated as control plots, which were not
23
mechanically scraped at any depth. The control and treatment plots in the experimental
sites are not to be confused with the lake-wide sites that also contain scraped and
unscraped samples, which refer to differences in water depth rather than experimentally
applied treatments. It should also be noted that in the experimental sites, control plots
were not necessarily devoid of all treatment, as they were still subjected to the managed
drawdown that occurred throughout the lake.
Effects of Environmental Disturbances on Muck Removal Project
Chapter 4 draws on results from both the lake-wide and experimental study sites
discussed above. There are also references to pre- and post-water-level regulation
periods, as well as pre-and post-restoration. Water-level regulation occurred in 1964
and the restoration project took place in 2004. Both pre-and post-restoration vegetation
communities are compared to pre-regulation (historical) communities, and care should
be taken as to which event the pre- and post- designations are referring to.
Throughout this paper, vegetation compositions will typically be classified as
communities, which in this case are simply a collection of species found at a specific
place and time. Some studies have used the term in an abstract sense, referring to
communities as a working mechanism or organism (e.g. Watt 1947), but throughout this
paper it will be used in a concrete sense, strictly for classification purposes (e.g.
McCune and Grace 2002). These groupings will represent specific abundances of one
or more dominant species relative to one another along measured environmental
gradients.
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CHAPTER 2 RESTORING LITTORAL VEGETATION PATTERNS WITHOUT KEY STRUCTURING
PROCESSES
Introduction
Restoration ecology has evolved from simple, succession-based approaches (van
der Valk 1998) to addressing multiple constraints and degradation thresholds (Suding et
al. 2004) as more complex systems and projects are undertaken. Regardless of the
system or subject of restoration, the primary task is usually to re-establish historical
structuring processes or key variables that have been lost and resulted in degradation
(Mitsch 1998, Hunt et al. 1999). This approach of restoring the structuring processes
necessary to re-establish a desired structure or species mix (pattern), relies on self-
organization and self-sustenance of communities, minimizing external influence or
energy inputs (Parker 1997). The frequency and intensity of fires, floods, and droughts
(disturbance regimes), for example, are often the focus of restoration in forest (Cissel et
al. 1999), prairie (Johnson and Matchett 2001), and wetland ecosystems (de Angelis
1998) because of their importance as key structuring processes.
The natural or historical range of variability of these processes have long been
used as guides to maintain diversity, restore ecosystems, and influence future
management actions (Landres et al. 1999). However, there are increasing numbers of
systems where key structuring processes, or the historical range of environmental
variability no longer exists, and restoring those conditions may not be economically or
socially feasible (Seastedt et al. 2008). For example, large-scale, intense burn regimes
that may have occurred historically cannot be safely implemented by managers, and
even small-scale, low-intensity burns may be unacceptable near urban areas (Stephens
and Ruth 2005). Many aquatic systems have altered flood/drought cycles that are
25
largely determined by water use or flood control needs (Hill et al. 1998, Havens and
Gawlik 2005), and restoring historical conditions would jeopardize surrounding urban
developments.
When key structuring processes are lost, external inputs (management efforts)
must increase to maintain or restore desired patterns, which can ultimately resemble
“intense gardening” or “landscape architecture” more than ecosystem restoration
(Mitsch and Wilson 1996). This can be a gradual occurrence; as species pools or
disturbance regimes slowly depart from historical conditions, management efforts
increasingly focus on removing unwanted species or the effects of those species (higher
fuel loads, increased peat deposition). Eventually these methods can constitute the
majority of management effort.
This removal-based approach has been criticized as not necessarily capable of
restoring any historical state, or even establishing a new, desirable state (Seastedt et al.
2008). Additionally, there are a growing number of examples where under prolonged
degraded conditions, biotic and abiotic interactions create new feedbacks that result in
resilience to restorative change, even if lost structuring processes could be restored
(Baker and Berdense 1999, Zedler 2000, Suding et al. 2004). Changing environmental
conditions (climate, disturbance regimes, etc.) and new combinations of
native/introduced species have led to the development of novel ecosystems (Suding et
al. 2004, Hobbs et al. 2006) and management strategies will have to be re-examined in
many cases (Seastedt et al. 2008).
While most examples of novel ecosystems in the literature are terrestrial, lakes
and wetlands could easily be at the forefront of this issue. Watershed development and
26
land use has long affected the hydrologic schedules, nutrient loads, and species pools
of virtually every aquatic system (e.g. Davis and Ogden 1997), and managers have
relied on removal-based approaches for decades to maintain desired patterns under
altered conditions (e.g. exotic or invasive species removal). Current environmental
problems resulting from past issues (regional expansion of exotics, unchecked nutrient
loading) can consume the time and budgets of managers (Seastedt et. al 2008), so that
new approaches and methods are slow to develop.
Most of our major water bodies are or will soon be permanently outside of their
natural range of environmental variability. Hydrologic schedules will likely be
increasingly determined by growing water supply and flood control demands, while
global climate change may affect the frequency, intensity, and duration of
flooding/drying events (Abrahams 2008). These new challenges could render traditional
management approaches un- or even counter-productive, and focus may have to shift
towards finding desirable or acceptable communities that provide biotic structure and
ecosystem services under new conditions (Seastedt et al. 2008).
This paper focuses on a lake restoration project in central Florida, USA, as an
example of the challenges facing many aquatic restoration projects in novel systems,
and of the need to develop new management approaches. Classic ‘removal-based’
management efforts have not been able to prevent degradation from various water,
nutrient, and species pool changes in this large, shallow, sub-tropical lake and
increasingly expensive and intensive methods of habitat manipulation have been
developed as a result (Moyer et al. 1995).
27
This paper focuses on a newer, intensive approach to lake restoration, where
bulldozers, herbicides, and drawdowns are used to maintain desirable, native
vegetation communities in a system now outside the range of natural variability. This
technique, dubbed "muck removal", was developed as a method of removing
accumulated organic material from the littoral zone, deposited after decades of
excessive vegetation growth under eutrophic and stabilized water conditions.
There is a long history of managers combating dense growth of aquatic vegetation
(Holm et al. 1969), as it can alter fish communities (Killgore et al. 1989), lower oxygen
levels, and impede navigation and flood control (Little 1968). Faced with increased
difficulty in implementing large-scale dry-downs, coupled with the rising costs,
inefficacy, and unpopularity of broad-scale herbicide applications, managers developed
a single, intensive disturbance effort to restore desirable communities. This approach
involves drying parts of the littoral zone, removing accumulated organic material and
unwanted, resilient species from the shorelines, and regulating initial vegetation
succession with herbicides. The goal is to create a sandy bottom habitat with sparse
emergent/submergent vegetation that supports important sportfish spawning and
improves boater access (Moyer et al. 1995). These conditions are considered historical
targets for muck removal restoration and are typical of systems with lower productivity
or higher levels of disturbance than what is seen in this degraded system (see Grime
1979).
This study represents far more than one state’s unique approach to combat
decades of habitat degradation; it serves as an example of how systems continually
change when important structuring processes are lost, and how management agencies
28
often rely on increasingly expensive, removal-based techniques despite criticisms of
these approaches for nearly a decade (Holling 2001). This chapter addresses one
important question facing restoration ecologists and poses another; can historical
vegetation structure or pattern be restored under novel conditions? If so, at what cost
should we maintain desired patterns when current processes no longer support them?
To answer the former question I compared vegetation communities after muck-removal
restoration (scraping) to early vegetation patterns before water levels were regulated in
the 1960’s. Specifically, I compared dominant species from the 1950’s to those
established in this study four years after restoration. It is my hope these results can be
used to address the latter question, and perhaps reemphasize the need to shift our
restoration targets and find new methods to manage ecosystems under increasingly
novel conditions.
Methods and Analyses
Lake Tohopekaliga (hereafter referred to as Lake Toho) is one of several large
lakes in the Upper Kissimmee River Basin in central Florida, USA. Each of these lakes
is successively connected and jointly regulated to collectively drain thousands of square
kilometers into the Kissimmee River and ultimately Lake Okeechobee (Ch. 1, Figure 1-
1). Toho is located near the top of this chain of lakes, covering 8,176 ha with an
average depth of 2.1 m (at maximum stage regulation of 16.75 m NGVD), with a
watershed of roughly 334 km2. Its volume has a large impact on water bodies
downstream when drawdowns are implemented, especially since all lakes farther down
the chain must be lowered to gravitationally drain Lake Toho (HDR Engineering 1989,
Remetrix LLC 2000).
29
Water control structures were installed on the Kissimmee Chain and Lake Toho in
1964 (Blake 1980), reducing the variability of lake stages by approximately 1.5 m, to an
annual range of 1.1 m (Ch. 1, Figure 1-2). Sewage effluent from up to three treatment
facilities was discharged into the lake from roughly 1940 to 1988, reaching a maximum
of 113 million liters per day in 1986 (Wegener et al. 1973). Decreases in water quality
and fisheries production in the late 1960's were attributed to stage regulation and
nutrient loading (Wegener 1969), beginning a series of drawdowns in 1971, 1979, 1987,
and 2004 as a means of improving fish habitat.
Lake-stage data were collected from a South Florida Water Management
District gauge located on the southern end of the lake, recording average daily water
levels since January 1942. Indicators of Hydrologic Alterations (IHA) software was used
to analyze pre (1942–1964) and post water-level regulation (1965–2008) periods,
defined by the completion of water control structures in 1964. Both periods were
analyzed for 30, 60, and 90 day maximum and minimum water levels, average monthly
levels, and quartiles. Two 10 year periods before and after regulation, 1944–1954 and
1992–2002, were selected for further comparison between pre- and post-regulation
periods. This was done to exclude some of the more extreme events in either period,
including historical highs and lows experienced in the early 1960s, as well as managed
drawdowns in the latter period. Water level structures were not completed on the
Kissimmee Chain of lakes until 1964, but it seems reasonable that substantial changes
were occurring in the watershed up to several years prior (beginning of construction),
possibly contributing to the historical highs (1960) and lows (1962) recorded just prior to
completion. Rather than use these events as representative of typical pre-regulation
30
fluctuations, the 10 year period characterized by more modest events and that occurred
just prior to early vegetation studies (1956) was chosen. These two periods allowed
comparison of relatively stable events, rather than just looking at differences in
maximum and minimum stage levels, which would also be affected by rare climatic
events. Water years were defined as June through May of the following year,
corresponding with the beginning of the wet season and end of the dry season,
respectively.
The largest muck removal project to date was implemented on Lake Toho in 2004,
when water levels were dropped from 16.8 m to 14.9 m from November 2003 until June
2004. Approximately 6.5 x 10^6 m3 of muck and vegetation were removed from over
80% of the shoreline and deposited at several upland sites, as well as 29 locations
within the lake (FFWCC 2004). Water levels returned to normal by August 2004.
Sample Locations
Lake Toho has a variable littoral zone in terms of slopes, wave energy, and
shoreline activities, which may result in differing plant communities. In order to capture
this variability and provide lake-wide inference for treatment effects, five monitoring sites
were selected from the less-developed, southern two-thirds of the lake that were
uninterrupted by outflows, jetties, or other notable features (Figure 2-1). The goal of site
selection was to represent the various habitat types and geomorphic conditions of the
lake without complicating restoration responses with shoreline development or unusual
features (creek outflows) within the plots.
Sites 1, 3 and 4 were located on broad, gently sloping areas of shoreline, while
Sites 2 and 5 were located on steeper, higher energy shorelines. Cattle ranching and
grazing was the primary land use in all but sites 4 and 5, which were bordered by
31
infrequent residential housing. These locations represented the majority of shoreline
community types and primary land use, giving the best inference as to lake-wide littoral
response to treatment.
#S
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Site 4
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Site 5Site 3
Sampling locations
0 – 6 ft depth classes
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1100 meters
Site 4
Site 1Site 2
Site 5Site 3
Site 4
Site 1Site 2
Site 5Site 3
Sampling locations
0 – 6 ft depth classes0 – 6 ft depth classes
Figure 2-1. Location of study sites throughout the lake. Each site encompassed the entire width of the emergent littoral zone, to approximately 2 m in depth. Sample locations were randomly located within depth stratifications of approximately 35 cm each.
Samples were collected from all water depths occupied by the emergent littoral
zone in order to monitor lake-wide vegetation changes, including those areas too deep
for mechanical removal but still subjected to drawdown. The boundaries of each site
were determined by placing a 60-ha rectangle on Digital Ortho Quarter Quads (DOQQ)
with 1-m2 resolution (1999) and bathymetric (Remetrix 2000) layers in ArcView GIS 3.2
32
software. The area of the rectangle remained constant but the shape was altered such
that it encompassed the zone of 0–2 m in depth (0–6 ft) (i.e., the sites on steep slopes
were stretched along the shore while those on gentle slopes extended much farther into
the lake).
Sampling locations were stratified by five depth classes of approximately 35 cm
(one foot) each (One = 30 – 65 cm, Two = 65-100 cm, Three = 100 – 135 cm, Four =
135 - 170 cm, and Five = 170 - 205 cm). The three shallowest classes (30 – 135 cm)
were located within the areas slated for mechanical muck removal, while the majority of
deeper classes (135 – 205 cm) were never dried enough or did not contain vegetation
communities targeted for restoration. Random coordinates were used to locate
samples in the field with a GPS (Global Positioning System) on each collection. The
shallowest areas sampled coincided with the approximate shoreward extent of muck
removal activities, which was roughly the 30 cm depth contour at maximum lake stage.
Three locations per depth class were sampled at each site for a total of 15 samples per
site, 75 total. Aboveground vegetation was clipped from 0.25 m2 circular quadrats at
each location, sorted by species, stems counted, and biomass recorded after excess
water was shaken off. Samples were collected each year during the summer (June)
and winter (December) seasons from June 2002 - June 2008, to account for any
seasonal variations in response and to increase the temporal intensity of sample
events. This resulted in 13 repeated measures for each location.
Lake-stage data were collected from a South Florida Water Management District
gauge located on the southern end of the lake, recording average daily water levels
33
since January 1942. Average water depths from three points at each sampling location
were referenced to lake stage data to approximate shoreline elevations across sites.
Historical vegetation data were referenced from agency studies conducted in
1956, eight years prior to water regulation (Sincock et al. 1957) and in 1971, seven
years after (Holcomb and Wegener 1971). These studies used intercept methods to
calculate frequency of occurrence along transects perpendicular to shore, with several
locations overlapping the sites in this study. While their methods vary considerably from
the sample techniques used in this study, they represent the only estimates of dominant
species and their distributions along shoreline elevations prior to stage regulation.
Analyses
Pre/post restoration comparison
Plant species density and biomass were summed across sub-samples within
depth classes for each sample event, resulting in five samples per site and 25 per
sampling occasion. While each depth class represented a subsample within a study
site, they were analyzed separately to determine water depth influences on vegetation
response. The December 2002 and June 2003 sample events were used to represent
pre-restoration conditions, and December 2007 and June 2008 samples were used as
post-restoration representatives. These times were chosen to capture littoral conditions
immediately prior to restoration and after vegetation communities re-colonized
mechanically-scraped areas. Importance Values (IV) were computed for each species
from the summed sub-samples by averaging the relative biomass and density of each
species in those sub-amples, and converting to a percentage value
IV = (Relative Biomass + Relative Density)/2 *100
34
Importance values were used to estimate species importance within a given depth
class and site as they are not biased towards large, few-stemmed species or small,
numerous-stemmed species. This calculation also relativized the dataset, eliminating
the need for transformations typically applied to density or biomass data that can vary
by orders of magnitude between species and samples (McCune and Grace 2002).
To reduce noise from rare species, only those with cumulative IV’s composing
99% of the total were retained for this analysis. Many studies eliminate species that
occur in < 1% of samples, but I used 1% of the total IV instead. This method is more
representative of the actual abundance of a species for the same reason IV’s are more
representative of a species’ abundance than frequency.
The resultant matrix consisted of 100 (50 pre and 50 post) samples and 21
species of the 37 encountered, and included a summer and winter sample event for
both the pre- and post-restoration periods. Although only 5 of these 100 samples were
independent (sites = 5), each depth class (5) and sampling occasion (4) were analyzed
separately in order to account for gradient responses and seasonal variation within
study sites. All analyses for the pre/post comparisons were performed on this matrix
and unless otherwise specified, were performed using PCORD software (McCune and
Mefford 1999).
Shannon-Weiner diversity indices were calculated from species biomasses prior to
eliminating rare species. The index was converted to effective numbers of species
(exponential of the diversity index), which is useful when comparing across groups due
to the non-linear nature of diversity indices (Hill 1973, Peet 1974). The effective number
35
of species in this case is essentially a measure of how many species were consistently
abundant relative to other species during that period.
Groups with similar species compositions were identified using a hierarchical,
agglomerative cluster analysis with flexible beta (-0.25) linkage and Sorenson distance
measures. These were chosen for their space conserving properties, compatibilities
with each other, and their advantages with non-normal data (McCune and Grace 2002).
Samples were grouped based on species IV's, using multiple species as a basis for
deciding on the fusion of additional groups.
An Indicator Species Analysis (ISA) determined the optimum number of clusters
for further analysis and defined those clusters in terms of representative species. This
analysis uses the proportional IV and frequency of a particular species in a particular
cluster relative to its IV and frequency in all other clusters (Dufrene and Legendre
1997). The optimum number of clusters was determined by which level produced the
most species with p-values < 0.05 in the indicator species analysis (McCune and Grace
2002). Species with low p-values (< 0.05) and high indicator values (> 40) were used
as community descriptors (cluster labels) in future analyses.
A Classification and Regression Tree (CART) model (S-Plus Tree Library, De’ath
2002) classified samples into the groups identified by the cluster analysis using the
measured environmental variables alone. We used the Gini index to measure impurity
(Breiman et al. 1984), cross-validation to select the best tree size (Vaysieres et al.
2000), and 1-Cross Validated Error as a more conservative estimate of variation
explained by the model (De'ath 2002). CART models were built using the combined
matrix of pre- and post-restoration communities in order to determine how muck-
36
removal effects varied temporally, spatially, and with water depth. Several
combinations of the variables water depth (at full pool) and hydroperiod were used as
continuous predictors, while site, scraping (for the post-restoration period), dominant
land use (cattle grazing, yes/no), and whether the sample occurred on a floating mat
were used as categorical variables.
A Multivariate Regression Tree (MRT) was built to identify communities based on
species IV’s and where they occurred along environmental gradients, and to compare
the results with those from the cluster analysis and CART model. This method uses the
sum of squared Euclidian distances about the multivariate mean of samples as an
impurity measure of each node, and each split is made to maximize the sum of squares
between nodes and to minimize it within nodes (De’ath 2002). Each leaf is then
characterized by the multivariate mean of its samples, the number of samples within
that leaf, and their defining environmental variables. The percent of variation explained
by the tree is reported as 1 - Relative Error, or more strictly 1 - Cross Validated Error.
In short, this technique partitions the samples into communities using both species
IV’s as well as the associated environmental variables, and provides the threshold
values for each partitioning variable. The resultant communities are defined not just by
species compositions (as in the cluster analysis) but where they occurred on the
environmental gradients as well, providing a different approach to community
delineation than the combined cluster and CART model methods. This method was
used as a confirmatory procedure, to verify groupings and distributional thresholds
identified in the previous analyses.
37
Nonmetric Multidimensional Scaling (NMS) ordinations were used to graphically
display community shifts from pre- to post-restoration periods using IV’s (McCune and
Grace 2002). Pearson correlations were calculated for species biomass and water
depths for each of the ordination axes. Vectors were used to track species composition
changes over time within sample units (sample position in species space), and
approximate boundaries were drawn onto ordination results to represent changes from
one community type to another, based on the afore-mentioned cluster analyses. Depth
classes were graphically separated from a single ordination to ease interpretation.
Temporal analyses
In order to track change in species biomass over time, I combined sub-samples of
biomass within each depth class, and then followed changes in species composition by
site, for two periods prior to restoration and for the last two periods of the study. Each
sampling period (pre = December 2002 and June 2003, post = December 2007 and
June 2008) consisted of 25 samples, five depth classes at each site of five sites. These
data were ordinated using NMS to graphically display changes in species abundances
throughout the period of study. Results were graphically separated after the ordination
by depth class for ease of interpretation.
Results
Hydrological Comparisons to Historical Record
Following regulation in 1964, annual fluctuations were managed between 15.9 and
16.8 meters NGVD, with flood events reduced by approximately 1.0–1.5 m (Ch. 1,
Figure 1-2). Average monthly water levels were similar when comparing pre- and post-
regulation periods, except for the early growing season (Figure 2-2). February and
38
March water levels were held higher and for longer duration after 1965, and dropped
more quickly to low pool by the end of the dry season (June).
The 10 year pre- (1944–1954) and post-regulation (1992–2002) periods had
similar mean, annual lake stages (16.45 and 16.40 m, respectively) and within-year
variation (0.61–1.91 St Dev and 0.63–1.01 St Dev respectively) (Figure 2-3). However,
inter-annual variations were considerably lower in the post-regulation period, with the
standard deviation of annual means falling from 1.09 prior to regulation, to 0.22 after.
The largest reduction in between-year variation occurred for the months of September
and October, where pre-regulation water levels for these months varied by 2 standard
deviations. From 1992 to 2002, standard deviations for these fall months were 0.26 and
0.34, respectively.
39
17.0
16.25
16.0
16.75
16.5
15.75
Lake
Sta
ge (M
eter
s N
GV
D)
Jun Jul Aug Sep Oct Nov Dec Jan Feb Mar Apr May
Figure 2-2. Monthly lake stage (Meters NGVD) for the pre-regulation period 1942–1964 (green), and post-regulation period 1965–2008 (red). The 75th percentiles are shown for the pre-regulation period.
40
15.00
15.50
16.00
16.50
17.00
17.50
18.00
6/1/1944 6/1/1947 5/31/1950 5/30/1953 5/30/1993 5/29/1996 5/29/1999 5/28/2002195319491944 1994 1998 2002
Pre-regulation1944-1954
Post-regulation1992-2002
15.5
16.0
17.5
16.5
18.0
17.0
Dai
ly E
leva
tion
(met
ers
NG
VD)
Figure 2-3. Daily lake stage (Meters NGVD) for a pre-regulation (1944–1954) and post-regulation period (1992–2002).
Vegetation Response
Total numbers of species encountered in the two pre- and two post-restoration
samples were 32 and 27, respectively, with frequency histograms showing similar
distributions among samples between the two periods (Figure 2-4). The majority of
samples had 2–3 species in each quadrat, regardless of sample period.
A histogram of scraped samples showing species changes over time displayed a
similar pattern, with the majority of quadrats having no change or a loss/gain of only one
species (Figure 2-5). When deeper water, unscraped samples (still exposed to artificial
41
dry-down) were included in the histogram there was a slight left skew, but no strong
pattern in overall species richness was evident throughout the study period.
0
5
10
15
20
25
1 2 3 4 5 6 7 8 9
Pre (32)Post (27)
Num
ber o
f Sam
ples
Number of Species by Sample
Figure 2-4. Frequency histogram displaying number of species per quadrat for all samples before and after restoration.
0
1
2
3
4
5
6
-5 -4 -3 -2 -1 0 1 2 3
Num
ber o
f sam
ples
Species Change by Sample
0
5
10
15
20
25
-6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6
Num
ber o
f sam
ples
Species Change by Sample
A B
Figure 2-5. Frequency histogram of species gain or loss by quadrat after restoration. A) Only those samples that were mechanically scraped, roughly 30–135 cm in depth. B) All samples, including those too deep for scraping but still exposed during the drawdown.
42
Shannon-Weiner diversity indices showed an increase in the number of effective
species in the scraped areas, from 5.3 to 6.2 after restoration. However, when including
those samples too deep for mechanical removal, there was a decline in diversity from
7.9 to 5.5 effective species, highlighting a loss from those areas that were only subject
to drawdown.
The cluster analysis revealed six distinct groups based on the number of indicator
species at each level of clustering, which resulted in approximately 50% of the
information remaining based on a scaled Wishart's objective function (McCune and
Grace 2002). Groups were labeled with species that had indicator scores of roughly 50
or greater in a given cluster (Table 2-1). These groups were 1) Pontederia cordata, 2)
Typha spp., 3) Hydrilla verticillata, 4) Paspalidium geminatum, 5) Panicum repens and
Eleocharis spp., and 6) Vallisneria americana.
Table 2-1. Indicator values (0–100) of species in the six groups identified by the cluster analysis. Those species with values of approximately 50 and greater were chosen as representatives of the corresponding group, or community. Species are coded as the first 3 letters of genus and first 2 of specific epithet (Pontederia cordata = PONCO).
P-value Species Group 1 2 3 4 5 60.0002 PONCO 71 12 0 0 0 00.0002 TYPSP 0 95 0 0 0 00.0002 HYDVE 0 4 50 25 0 90.0002 PASGE 0 0 17 73 0 30.0002 PANRE 8 0 0 0 81 00.0002 ELESP 1 1 0 0 48 00.0002 VALAM 0 0 0 0 2 92
Community correlations to measured environmental variables were determined by
CART models. The best model was pruned to nine leaves based on the 1 - cross
validated error method, and used water depth at maximum lake stage, muck removal
(y/n), sample period (pre/post-restoration), and whether the sample was on a grazed
43
shoreline (Figure 2-6). The CART model had a cross validated error of 0.36, and a
misclassification rate of 17%, explaining 64% of the variation in the dataset. Water
depth at maximum lake stage was the most important predictor variable, followed by
muck removal, sample time, and cattle grazing (yes or no). Sample time was
incorporated into this analysis as a surrogate for the artificial dry-down that all samples
experienced, regardless of whether or not their water depths allowed mechanical
removal of soil and vegetation. Samples that changed community types following the
restoration but did not actually get scraped were considered to exhibit dry-down effects.
Each of the six communities identified in the Cluster and ISA analyses were
classified in the CART model, with Typha and P. geminatum having the smallest
number of samples (4) and Vallisneria having the most (22 & 4). While water depth
explained more of the variation in the model, muck removal was responsible for the
primary division of the data. Vallisneria was predicted to occur in scraped areas of
shoreline at depths > 98 cm, up to approximately 135 cm, or the maximum scraped
depths. P. repens and Eleocharis spp. dominated the shallowest scraped samples
(approx. 30–98 cm).
As expected, unscraped communities (no muck removal) were much more
variable, as they included pre-restoration samples as well as post-restoration samples
too deep for mechanical scraping. Water depth differentiated the two, as the maximum
depth scraped was approximately 135 cm. Seven of the leaves in the tree were
classified as unscraped, with the majority of samples predicted as Pontederia (18)
dominating 30–109 cm in depth.
44
Not Scraped
Depth < 109 cm
Pre
Depth < 98 cm
Scraped
> 127 cm
> 160 cm< 166 cm
>184cmPONCO
(18)TYPSP
(4)
HYDVE(14)
VALAM(4)
HYDVE(14)
PASGEHYDVE
(10)
PASGE(4)
PANREELESP(10)
VALAM(22)
Post
PONCOTYPSPHYDVEPASGEPANRE_ELESPVALAM
Figure 2-6. CART model of pre-post restoration periods (9 groups, CV error = 0.36, Misclass rate = 17%). Bargraphs under leaves represent proportion of samples in that leaf classified as the corresponding community. Numbers in parentheses under the leaves indicate how many samples are in each leaf. Rank of variable importance was water depth, muck removal, sample period, and grazing.
Prior to restoration, the Hydrilla and the P. geminatum communities were predicted
to occur intermittently at > 127 cm of water depth, either as individual communities or
grouped as one. Following the restoration, Hydrilla distributions were somewhat
reduced, with Vallisneria replacing that community in 127–160 cm of water, regardless
of whether or not samples were scraped. Typha was classified in just four unscraped
samples, at 109–127 cm in depth, all of which were later scraped. Essentially, the 18
samples classified as Pontederia, 4 as Typha, and 14 classified as Hydrilla (36 total), all
45
became Vallisneria (22 & 4) or P. repens and Eleocharis (10) after restoration,
depending on water depth.
These same data were used to track changes in species compositions of
individual sample units over time using an NMS ordination (Figure 2-7). The final
solution was three dimensional, accounting for 68% of the variance with 54% in the
primary two axes. Total biomass per sample was correlated with Axis 2 (R2 = -0.41)
and water depth with Axis 1 (R2 = 0.72), having a final stress of 16.8 and an instability of
0.002. These values lie within the ranges typically seen with ecological community
datasets (McCune and Grace 2002).
The ordination results were graphed in the two primary dimensions, and
approximate community boundaries were drawn in to highlight shifts in community type
over time. Water depth classes were pulled apart into separate graphs to ease visual
interpretation of 25 different sample units moving through four time periods (Figure 2-8).
Due to the Pearson correlations with ordination axes, Axis 1 can be approximated with
water depth (R2 = 0.72) and Axis 2 with decreasing total biomass (R2 = -0.41).
46
Pontederia
Vallisneria
Hydrilla
P. geminatum
P. repensEleocharis
Typha
Axis 1 - Water Depth (R2 = 0.72)
Axi
s 2
-Bio
mas
s (R
2=
-0.4
1)
Figure 2-7. NMS ordination of two pre- and two post-restoration sample periods. Approximate community boundaries based on cluster groupings were outlined on the ordination for ease of interpretation. Pearson correlations (R2) with axes were: Water depth = 0.72 to Axis 1, Total biomass = -0.41 to Axis 2.
47
PONCO
VALAM
HYDVE
PASGE
PANRE_ELESP
TYPSP
Axis
2
Axis 1
All 30 – 65 cm
170 – 205 cm
65 – 100 cm
100 – 135 cm 135 – 170 cm
PONCO
VALAM
HYDVE
PASGE
PANRE_ELESP
TYPSP
PONCO
VALAM
HYDVE
PASGE
PANRE_ELESP
TYPSP
Axis
2
Axis 1
All 30 – 65 cm
170 – 205 cm
65 – 100 cm
100 – 135 cm 135 – 170 cm
Figure 2-8. NMS ordination of two pre- and two post-restoration sample periods. Approximate community boundaries based on cluster groupings were overlayed onto the ordination, and arrows show movement of samples through species space over time. Large movements indicate large changes in species compositions, and vice versa. Depth classes were pulled from the same ordination to ease interpretation. Pearson correlations (R2) with axes were: Water depth = 0.72 to Axis 1, Total biomass = -0.41 to Axis 2.
Similar to the CART model, the shallowest depth class went from a Pontederia
community to P. repens following restoration, while the second depth class moved from
either Pontederia or Typha to Vallisneria. This depth class saw the largest change in
species composition, as evidenced by the amount of distance between the pre- and
post-restoration samples.
The 3rd depth class contained several community types prior to the muck removal,
including Pontederia, Typha, and Hydrilla; all but the Hydrilla community changed to
48
Vallisneria following restoration. The fourth depth class was beyond muck-removal
depths, but also shifted primarily to Vallisneria from either P. geminatum or Hydrilla after
restoration. The deepest samples remained largely unchanged, grouped as either
Hydrilla or P. geminatum communities.
The MRT had a higher error rate than the CART model (CV error = 0.55)
explaining only 45% of the variation in the dataset (Figure 2-9). Including site location
and sample season improved the fit slightly, but I was more interested in isolating how
mechanical scraping and dry-down varied by water depth, and wanted to simplify the
tree (minimize number of leaves) in order to ease interpretation. Site differences that
were delineated in alternative models were not attributed to obvious anomalies (grazing
pressure, shoreline slope, dominant wind directions, etc.) and so were considered as
local variations and not included as a variable in the final model.
Even without accounting for more than 50% of the variation in species
abundances, the MRT still showed very similar results to the CART model and cluster
analysis. Most of the dominant species in the final nine groups were listed as indicator
species, and their positions along the gradients were very similar to the CART model.
There were essentially seven groups identified in the nine leaves of the tree, with the
primary differences between the MRT and CART being the absence of Typha, the
addition of Nuphar advena, and the splitting of the Pontederia group to include a
shallower Luziola fluitans community.
49
Not Scraped
> 98cm < 123cm
< 160cm
<166cmPre
Post
> 65cm
LUZFLPANREPONCOALTPHTYPSPHYDVENUPADPASGEELESPVALAM
(10) (22)
(12) (12)
(4)
(16)(4)
(6) (14)
LUZFL VALAM
HYDVE
PASGE
HYDVEVALAM
LUZFL PONCO
HYDVE
Scraped
Figure 2-9. MRT model of pre-post restoration periods (9 groups, CV error = 0.55). Bargraphs under the leaves represent the proportion of each species in that group. Numbers in parentheses under the leaves indicate how many samples are in each leaf. Rank of variable importance was water depth, sample period, muck removal, and grazing. Only the most common of the 21 species are shown.
The primary division was attributed to muck removal, with the scraped samples
again dominated by P. repens and Eleocharis spp. at < 98 cm in depth, while everything
in 98–135 cm was dominated by Vallisneria.
There were also similar groups among the unscraped samples, with the next
division occurring at 123 cm in the MRT, as compared to 109 cm in the CART model.
The unscraped samples at < 123 cm were dominated by either Pontederia or Luziola,
50
the same as the CART model, but were further divided at 65 cm in depth with the
shallowest community classified as Luziola.
The deep water communities were also quite similar to the CART model, with
Hydrilla, P. geminatum, and Vallisneria all dominating at varying depths > 123 cm. The
MRT again identified temporal shifts from Hydrilla to Vallisneria even in the unscraped
samples, but also revealed a loss of Nuphar over time as well. Samples > 160 cm in
depth were again dominated by either P. geminatum or Hydrilla, as in the CART model.
Biomass plots showed similar patterns in dominant species change after
restoration, and highlighted the dramatic loss of floating leaf aquatics and Typha that
were subtle in the analyses based on importance values (Figure 2-10). These
communities were relatively infrequent in study samples, but both lost 100% of their
sampled biomasses after restoration. Pontederia, the most common species and
primary target of the mechanical removal project, lost 88%. Similar to the importance
value analyses, Vallisneria had by far the largest increase in biomass among the
species (from 0 to 14.6 kg), but Hydrilla and P. repens, both exotics, increased
biomasses 137% and 58%, respectively. P. geminatum was very prevalent in the
deepest samples and as evident in the ordination tracks, showed very little change in
biomass between time periods.
51
-40
-30
-20
-10
0
10
20TYPSP
PONCO
Pads
PASGE
PANRE
HYDVEVALAM
-100%
-2%
-88%-100%
137% 58% N/A
Figure 2-10. Changes in biomass of common species (in kilograms wet weight), including Nuphar advena and Nymphaea odorata grouped as lily pads. Biomass gain or loss is also expressed as a percentage of pre-restoration biomass, unless a species was not recorded previously (Vallisneria).
Discussion
Historical Comparisons
The primary goal of this restoration project was to replace robust communities that
became established after years of elevated nutrient levels and stabilized water
schedules, with communities more typical of the dynamic, lower-nutrient system that
occurred historically (sparse macrophyte coverage and sandy substrates). Ideally, this
would be accomplished by re-establishing the range of environmental variation,
including nutrient levels (Moss et al. 1996), hydrological regime (Middleton 1999), and
species pools (Cole 1999). While point-source nutrient reductions (James et al. 1994)
52
and selective species removals (Moyer et al. 1989) have been the focus of past
management activities on the lake, annual water regulation schedules have been
unchanged for over 40 years. As early as 1969, managers recognized the need to
incorporate larger fluctuations into annual schedules (Wegener 1969) but, like many
ecosystems today, this was hindered by flood control and water use demands in the
changing watershed. Instead, management efforts focused on species removal, rather
than addressing changes in processes that may have led to their establishment.
For example, over a 10 yr period just prior to restoration (1992–2002), the
shoreline elevation occupied by the dominant Pontederia community was flooded 78–
99.9% of the period. The deepest edge of this community essentially never dried, and
the shallowest edge was flooded by up to 83 cm of water during high water events.
During a typical 10 yr period prior to regulation (1944–1954), however, this shoreline
elevation was flooded only 66–96% of that period, with water receding 18 vertical cm
below the deepest edge of the community during low water events, and flooding the
shallowest edge by up to 1.7 meters of water during high water events.
Besides a reduction in the magnitude of water level variations, there was also a
substantial difference in the timing of annual fluctuations after water-level regulation.
Historically, high water events consistently occurred in early winter (October and
November), and shifted to early spring (February and March) after stabilization.
Additionally, the early spring levels are now higher than they were historically, and drop
more suddenly to match annual lows in May and June.
Water levels in the early growing season can have a big influence on species
compositions (Weiher et al. 1996), limiting germination to more flood tolerant species, or
53
promoting vegetative growth from established perennials. Likewise, the timing (van der
Valk 1981, Seabloom et al. 1998), frequency, and duration of flooding (Squires and van
der Valk 1992) largely influences species compositions in wetland systems. The
dramatic change in magnitude, seasonality, and frequency of flooding/drying events are
likely the primary reason for a shift in dominant vegetation type since stage regulation.
Under the dynamic lake-levels of the 1950's, the shoreline elevations in this study
were dominated by grassy species, namely P. repens, Paspalum spp., and Luziola
(Sincock et al. 1957). While this period and habitat was often referenced as the target
for shoreline restoration on this lake (sandy substrate, sparse emergent grasses), the
dominant species prior to regulation was an invasive exotic grass (P. repens) that was
originally introduced for grazing cattle (Tarver 1979). This same species has had
dramatic impacts in other Florida lakes (Smith et al. 2004) and is continually regulated
with herbicides by the Bureau of Invasive Plant Management (Schardt 1994). During
the 1950's, however, P. repens was not considered a nuisance on Lake Toho, and was
described as an important species that provided cover during higher water (Holcomb
and Wegener 1971).
This a good example of the difficulty in defining the ‘natural’ or historical state of
systems (Landres et al. 1999), as well as how restoration targets can often be biased or
value-laden perceptions of what a system should resemble rather than what it was prior
to human-induced changes (Zweig and Kitchens in press). In this particular case, the
restoration target appeared to resemble the habitat structure (sparse emergent grasses)
that was established in the 1950’s, but there is no record of a similar, native-dominated
community having ever occurred on the lake.
54
Prior to restoration activities in 2004, a grassy community like that described in the
1950’s was found in my study areas, but was restricted to narrow bands near the annual
high water lines (< 58 cm) and was dominated by P. repens and Luziola. The lower
elevations that it occupied historically were dominated by more competitive emergent
species, primarily Pontederia and the invasive exotic Alternanthera philoxeroides,
neither of which were identified in the 1950's (Sincock et al. 1957). Four years after
restoration, there was a marked decrease in the Pontederia community but it was not
replaced by the grassy communities that existed historically. Instead there was a
dramatic expansion of submersed aquatics, whose composition and abundance were
unprecedented in this system.
Vallisneria, a native, submersed species, dominated scraped sections of shoreline
four years after restoration, although it was extremely rare prior to restoration. While
this plant had been recorded in the 1950’s, it was at lower elevations (deeper water)
and at very low frequencies (0–3%) in comparison to this study (Sincock et al. 1957).
By 1970–1971 Vallisneria had moved shoreward nearly 60 vertical centimeters,
expanding into elevations similar to where it was found at the end of this study, but its
frequency of occurrence was still only around 3% (Holcomb and Wegener 1971).
Hydrilla, another dominant submersed species in this study, expanded in both the
scraped and unscraped areas following restoration, and was never recorded on Lake
Toho prior to 1972.
Historically, Lake Toho was described as having low alkalinity and was not
considered to support many submersed plants, and water-level stabilization was
predicted to have little impact on their abundance (Sincock et al. 1957). Since that
55
period, nutrient pollution, water stabilization, and the introduction of the “Perfect Aquatic
Weed” Hydrilla (Langeland 1996), submersed species have occupied large portions of
the lake, and have hindered navigation and even flood control (BIPM 2004). This is
another indication of the magnitude of change since water level regulations took place,
and how dissimilar post-restoration communities remained from those in historical
records.
Management Implications
The muck removal application conducted on Lake Toho was the largest and most
intensive removal event to date, and was used as a substitute for the loss of historic
flood/drought cycles that would have naturally flushed/oxidized accumulated organic
materials or floating mats during such events. This unique approach was an attempt to
reset decades of succession by removing the species, seedbanks, and soils associated
with degraded shorelines. Initial colonization was regulated with selective herbicide
applications, in an effort to force historical patterns on the sandy, exposed shorelines
without the historical processes that maintained the system originally.
Ecosystem restoration will increasingly involve finding new methods or
mechanisms to produce desired pattern where key drivers have been lost (Williams
2007). Global warming and human population growth is pushing many systems outside
of their historical range of variability, and many lost processes may not be restorable.
The prevalence of novel ecosytems, or the existence of new communities evolving
under changing environmental conditions and altered disturbance regimes (Suding et al.
2004), may require shifting restoration targets from focusing on historical states to
finding new, potentially more beneficial ecosystem conditions (Chapin et al. 2006).
56
This study is a good example of the difficulty in applying traditional, removal-based
management approaches with increasing efforts, attempting to maintain historical
patterns under degraded conditions. After 30 years of gradually intensifying
management techniques (Wegener and Williams 1974, Moyer et al. 1989), the largest-
scale muck removal project ever implemented still failed to restore historical littoral
patterns on Lake Toho. The dense, monocultural Pontederia community that dominated
for at least 20 years after hydrologic and nutrient changes in the system promoted its
expansion, was replaced by yet another novel, submersed community that was
previously only documented at very low frequencies (Sincock et al. 1957, Holcomb and
Wegener 1971, Moyer et al. 1989).
While the objective of establishing the historical pattern of sparse, emergent
grasses was not realized, the community that did establish along the treated shorelines
had similar desirable attributes as the target habitat. For example, organic soils were
replaced with sandy substrates, the submersed communities provide important habitat
for fish (Barnett and Schneider 1974) and waterfowl (McAtee 1939, Sculthorpe 1967),
and the removal of floating mats and dense emergent vegetation allows for better
recreational access.
When system degradation cannot be reversed at an acceptable cost, managers
should strive for the biotic structure and ecosystem services that stakeholders desire,
while promoting communities that are both feasible and resilient (Seastedt et al. 2008).
This project has been successful at the former, but the resilience or longer-term
establishment of a submersed community at these lake elevations is unknown. The
vertical range of shoreline occupied by the submersed community will likely compress to
57
only those areas with 100% annual hydroperiods under normal regulations (see Ch. 4),
and aggressive emergent species have already been re-established in the shallow
regions of this study. A regional drought could expose most of the shoreline occupied
by the newly established submersed community, allowing rapid invasion by emergent
species like Pontederia, or perhaps more likely, P. repens; this species has previously
displaced thousands of hectares of native marsh after low water events on other Florida
lakes (Smith et al. 2004). Without substantial changes in water regulation schedules, it
is likely that Pontederia will continue to expand lakeward from its narrow bands along
the shore, as happened under similar conditions from 1979 to 1987 (Moyer et al. 1989).
The importance of hydrological conditions to wetland control and structure is
widely recognized (National Research Council 1996), and restoration of these systems
must begin with hydrology (Hunt 1999). The communities established on Lake Toho
following restoration may be dependent on consistent herbicide applications, which are
increasingly regulated and dependent on currently declining state budgets (BIMP
2004). While restoring the variability of the natural hydrological regime is not possible in
this or many other aquatic systems, it is possible that partial improvements to
hydroperiods could be of value (Zedler 2000). For example, Lake Toho is consistently
managed between 15.9 to 16.8 meters (NGVD) annually, with little to no inter-annual
variability (excluding infrequent drawdowns). Year to year fluctuations are known to
increase plant diversity, and can essentially double the number of vegetation types on a
shoreline (Keddy and Fraser 2000). Managing lake levels with 0.5 m of inter-annual
variation, for example, may reduce the amount of herbicides needed to keep robust,
resilient communities from dominating the zone of intra-annual variation.
58
In many cases, the sequence of disturbances (including floods and droughts) and
their timing, intensity, and spatial pattern have greater impacts than single, intensive,
large-scale events (Barlow and Peres 2006). Since the 1970's, intensive, managed
drawdowns were conducted on Lake Toho at approximately 10 year intervals to
counteract effects of water stabilization. It is possible that incorporating year-to-year
fluctuations would have a greater impact on littoral communities than infrequent, drastic
drawdowns. The dense emergent communities established between these rare events
proved too robust to be displaced by periodic droughts, and appear well adapted to the
degraded environmental conditions of the lake.
Additionally, large-scale, intensive disturbances may have profound impacts
(Turner et al. 2003), but their outcomes are difficult to predict and are risky to
implement. The first drawdown implemented on the lake in 1971, for example, was
followed by a substantial drought, keeping lake levels below normal for nearly two years
(Wegener and Williams 1974). Even if results similar to this study could be expected
from large-scale, muck-removal treatments among other shallow, subtropical systems,
they would likely vary considerably depending on environmental conditions during and
directly after application. Had this treatment been followed by a prolonged drought, for
example, we might expect shorter hydroperiod communities to have colonized treated
areas, instead of the submersed species found in this study.
Ecosystem restoration should stay focused on key structuring processes and
promoting desired ecosystem functions under future conditions. The large-scale muck-
removal project implemented in this study did not re-establish littoral vegetation patterns
that occurred prior to water-level regulation, but resulted in an unprecedented
59
expansion of submersed species instead. While the novel, submersed community that
became established is preferred by managers over the pre-restoration habitats, it is
unclear whether it will persist under degraded environmental conditions and unchanged
water regulation schedules. This study will hopefully serve as an example of the need
to focus management and restoration efforts on establishing communities that will
persist under current and projected conditions with minimal maintenance and effort.
Even as recent studies have called for accepting new communities instead of historical
states (Seastedt et al. 2008) and promoting new approaches to managing under novel
conditions (Holling 2001), we must keep the basic premise of successful restoration
efforts. Restoring or at least partially implementing key structuring processes (Landres
et al. 1999) should remain at the forefront of pattern restoration, and will minimize
management contributions and costs (Mitsch and Wilson 1996). Hydrological regimes
will become increasingly difficult to restore with population growth and changing
precipitation patterns, and with it the temptation to maintain pattern with herbicides,
species removals, and bulldozers.
60
CHAPTER 3 MUCK REMOVAL AS A TOOL FOR RESTORATION OF LITTORAL VEGETATION ON
A SUBTROPICAL LAKE
Introduction
Much of the literature on shallow lake restoration typically involves reducing water
column turbidity and reestablishing aquatic macrophytes, either through reducing
planktivore biomass, stocking piscivores (top-down approach), or reducing nutrient
loads, thereby reducing phytoplankton and increasing light penetration to the sediments
(Jeppeson et al. 1990, Moss et al. 1996). These studies are based on the phenomenon
of alternative stable states, where shallow, eutrophic lakes can occur in either a
degraded state (turbid water, phytoplankton-dominated) or in a clear-water, macrophyte
dominated state, under the same environmental conditions (Scheffer et al. 1993).
Transitions between these states can occur rapidly, switching from plant to algae-
dominated conditions after water fluctuations (Blindow et al. 1993), plant removal (van
Donk and Gulati 1995), or changes in the food-web structure (Carpenter and Pace
1997).
However, in warm temperate (Romo et al. 2005) and subtropical lakes (Bachmann
et al. 2002) the correlation between high plant density and clear water is much weaker.
In Florida lakes, for example, turbid water can still support high macrophyte coverage,
and lake restoration projects typically involve vegetation removal, rather than
establishment. This approach is seemingly at odds with much of the shallow lake
restoration literature, but controlling aggressive and dense growth of littoral vegetation is
a primary goal in this region.
Florida lakes are subject to the same pressures facing most waterbodies near
urban development, including modified lake stages (Havens 2005), elevated nutrient
61
levels (Bachmann et al. 1999), exotic species invasions (Smith et al. 2004), and
shoreline modification (Light and Dineen 1994). Usually, such conditions result in
degraded, turbid systems, but strict environmental regulations and relatively large
aquatic management budgets in the USA have improved conditions over the last few
decades; eliminating point-source pollution, implementing fish harvest plans, promoting
management of sport fish habitat, and continually removing invasive exotic plants
(Moyer et al. 1989, Williams 2001, Allen et al. 2003). Much of Florida lake management
has moved beyond reestablishing macrophytes in degraded systems, and focuses now
on regulating the abundance, distribution, and composition of the established littoral
vegetation (FFWCC 2003).
There are several factors contributing to prolific littoral vegetation growth in
Florida’s lakes: 1) Nutrient concentrations have been reduced from their highest levels,
but non-point source pollution (Havens 1995) and internal loading mechanisms
(Bachmann et al. 1999) can maintain higher levels than occurred historically, 2) Strictly
regulated water schedules maintain predictable, relatively stable hydrological conditions
(HDR Engineering 1989), 3) Aggressive exotic species, including emergent (e.g.
Panicum repens), floating (e.g. Eichhornia crassipes), and submersed (e.g. Hydrilla
verticillata) genotypes, are capable of rapid expansion in these warm-water, eutrophic
systems, and 4) Large area:volume ratios (large photic zones) can result in up to 100%
of the lake bottom capable of supporting rooted aquatic vegetation (Canfield and Hoyer
1992).
Lake restoration in this region has shifted from vegetation establishment to
removal, because without dynamic water schedules, dense emergent vegetation can
62
form floating mats around the annual low-pool elevation of the shorelines (Hoyer and
Canfield 1997), possibly leading to a loss of sport fish spawning habitat, recreational
access, open water area or functional lake size, plant diversity, and lower oxygen levels
(Moyer et al. 1989). Typical management responses include mechanical harvest of
floating mats (Mallison et al. 2001), regular herbicide control of aggressive species
(Schardt 1997), and implementation of managed droughts (drawdowns), which expose
organic mats to oxidation and subsidence (Wegener et al. 1973). However, the short-
term benefits of these procedures (Moyer et al. 1995) and the increasing difficulty of
implementing drawdowns in urban watersheds have led managers to search for new
approaches, including mechanical scraping to remove muck and vegetation (hereafter
referred to as muck removal).
Muck removal involves scraping (with bulldozers) vegetation and accumulated
organic materials from exposed portions of the littoral zone during drawdowns, and may
include regulating initial plant succession with herbicides. This technique has been
applied to several lakes in Florida, and has been considered successful in improving
short-term juvenile sport-fish abundance (Moyer et al. 1989, Allen et al. 2003).
Although no long-term faunal or vegetation monitoring was conducted on early projects,
increasingly larger applications have been attempted since its inception. The largest of
these applications took place on Lake Tohopekaliga in central Florida, where
approximately seven million cubic meters of shoreline vegetation and underlying soils
were removed from roughly 1500 ha of the perimeter in 2004.
The goal of this study was to determine the efficacy of this procedure by
comparing pre- and post- restoration vegetation communities, in both scraped and
63
unscraped treatment plots. Specifically, I tested whether muck removal resulted in
different vegetation communities than a typical managed drawdown, and if so, how
those responses varied by water depth and recovery rates. These results are important
to lake restoration practitioners and aquatic plant managers, especially as goals shift
beyond simply re-establishing vegetation and begin managing for specific habitat types.
Methods and Analyses
This project was conducted on Lake Tohopekaliga (hereafter referred to as Lake
Toho), one of several large lakes in the Upper Kissimmee River Basin in central Florida,
USA. Each of these lakes is successively connected and jointly regulated to collectively
drain thousands of square kilometers into the Kissimmee River and ultimately Lake
Okeechobee (Ch. 1, Figure 1-1). Toho is located near the top of this system, and
covers 8,176 ha with an average depth of 2.1 m (at maximum stage regulation of 16.75
m NGVD). This volume of water effects systems downstream when stage levels are
manipulated (e.g. Lake Okeechobee, Kissimmee River), specifically since the entire
chain of lakes must be lowered in order to gravitationally drawdown lakes in the
northern region of the chain (HDR Engineering 1989, Remetrix LLC 2003).
Water control structures were installed on the Kissimmee Chain and Lake Toho in
1964 (Blake 1980), reducing the range of water level fluctuations by approximately 1.5
m to an intra-annual variability of 1.1 m (Ch. 1, Figure 1-2). Sewage effluent from up to
three treatment facilities was discharged into the lake from roughly 1940 to 1988,
reaching a maximum of 113 million liters per day in 1986 (Wegener et al. 1973). The
combined impacts of stage regulation and nutrient loading were blamed for decreases
in water quality and fisheries production in the late 1960's, leading to a series of artificial
dry-downs in 1971, 1979, 1987, and 2004 to improve fish habitat.
64
The largest muck removal project to date was implemented on Lake Toho in
2004. Water levels were dropped from 16.8 m to 14.9 m from November 2003 until
June 2004, during which time roughly 6.5 x 10^6 m3 of muck and vegetation were
removed from roughly 1500 ha of shoreline lake bottom. Spoil was deposited at several
upland sites and in 29 locations within the lake (FFWCC 2004). Water levels returned
to normal by August 2004.
Sample Locations
Three study sites spanning 1600 m (approx. 1 mi) of shoreline each were located
in areas with similar depth contours, vegetation communities, and shoreline use, in
order to minimize inter- and intra-site variation that might confound treatment results.
Sites were selected to represent the habitat targeted by muck removal projects, which in
this case was primarily a band of dense pickerelweed (Pontederia cordata) and floating
mats of vegetation (tussocks), which occurred roughly within the range of annual water
level fluctuation. Plot sizes also had to be of functional value to avian and
herpetofaunal communities for concurrent studies monitoring their responses to
treatment. Each study site was therefore split into four treatment blocks of 400 m each,
the size of which severely limited the amount of replicate sites available (Figure 3-1).
The spatial extent of each study plot and the reluctance of lake managers to reserve
multiple control sites throughout the lake resulted in just three locations isolated for
experimental treatment.
These sites were originally structured as a randomized complete block design,
with three treatments and a control randomly assigned to four blocks at each site.
However, two of the planned treatments were dropped by managers after pre-sampling
was completed, so a control and treatment were randomly assigned twice within each
65
study site. This complicated the sample design as treatments and controls were
replicated within and between sites. Due to the efforts in minimizing inter-site variation
during site selection and the dearth of replicates, I used each treatment as an
independent sample to increase the sample size. Ideally, additional control sites would
have been established on adjacent, similar lakes, but due to linked hydrologies and
gravitational drawdown, other lakes of similar size and region were also lowered during
this application. Therefore, the design of this project was limited by cost, logisitics, and
treatment restrictions, and I feel the best sampling protocol was established given the
constraints. The maximum water depth of the plots, or the lakeward extent, was
delimited by the approximate water depths mechanical scraping could be applied, from
roughly 35 - 135 cm water depth at maximum lake stage.
66
None (Control)
N
N
S/H
Site 3
S/HN
N
Site 1
N
S/H
NSite 2
Sc raped w / Herb icide
Sc raped w / Herb icide
None (Control)
None (Control)
Sc raped w / Herb icide
Sc raped w / Herb icide
25 m Spr ay Bu ff er
0123
45 De pth clas se s (fe et)
De pth clas se s (fe et)
54
32
10
25 m Spr ay Bu ff er
6
De pth clas se s (fe et)5
43210
25 m Spr ay Bu ff er
S/H
None (Control)
None (Control)
Sc raped w / Herb icide
S/H
Sc raped w / Herb icide
None (Control)S/H
N
S/H
N
Scraped w/ Herbicide
None (Control)
Depth classes (feet)
54
32
10
25 m Spray Buffer
6
Scraped w/ Herbicide
None (Control)S/H
Figure 3-1. Location of experimental study sites on a bathymetric map of Lake Toho (0–13 ft, or ~ 2 m). White plots were designated controls, while blue plots were treated with mechanical muck removal and periodic herbicide applications.
Sampling locations were stratified by three depth classes ( One = 35–68 cm,
Two = 69–102 cm, Three = 103–135 cm) and were located on maximum slopes of 30
cm change over 30 m in distance, so as to avoid unusual shoreline contours. This was
accomplished by placing 30 x 30 m grids onto a GIS bathymetry layer (Remetrix 2003)
and randomly selecting grid numbers from each depth category. Centroid coordinates
were used to locate samples in the field with a GPS (Global Positioning System) on
each sampling occasion. Two locations per depth class were sampled from each
treatment plot for a total of six samples per treatment, and 12 total treatment plots.
67
Aboveground vegetation was clipped from 0.25 m2 quadrats at each location, sorted by
species, stems counted, and biomass recorded after being oven-dried to a constant
weight (70 deg C). Samples were collected each year during the summer (May-June)
and winter (December) seasons from June 2002 to June 2008, resulting in 13 repeated
measures for each location.
Soil cores were collected from the top 10 cm of substrate from each sampling
location in June 2003 and June 2008, using cylindrical aluminum corers measuring 7
cm in diameter. Samples were placed on ice until moved to a freezer at the University
of Florida, Gainesville, FL. After being oven dried to constant weight, bulk densities
were determined (Blake and Hartge 1986) and percent organic content was calculated
by loss on ignition (Chapman and Pratt 1961, Jacobs 1971).
Lake-stage data were collected from a South Florida Water Management
District gauge located on the southern end of the lake, recording average daily water
levels since January 1942. Indicators of Hydrologic Alterations (IHA) software was used
to analyze pre (1942–1964) and post water-level regulation (1965–2008) periods,
defined by the completion of water control structures in 1964. Both periods were
analyzed for 30, 60, and 90 day maximum and minimum water levels, average monthly
levels, and quartiles. Two 10 year periods before and after regulation, 1944–1954 and
1992–2002, were selected for further comparison between pre- and post-regulation
periods. This was done to exclude some of the more extreme events in either period,
including historical highs and lows experienced in the early 1960s, as well as managed
drawdowns in the latter period. Water level structures were not completed on the
Kissimmee Chain of lakes until 1964, but it seems reasonable that substantial changes
68
were occurring in the watershed up to several years prior (beginning of construction),
possibly contributing to the historical highs (1960) and lows (1962) recorded just prior to
completion. Rather than use these events as representative of typical pre-regulation
fluctuations, the 10 year period characterized by more modest events and that occurred
just prior to early vegetation studies (1956) was chosen. These two periods allowed
comparison of relatively stable events, rather than just looking at differences in
maximum and minimum stage levels, which would also be affected by rare climatic
events. Water years were defined as June through May of the following year,
corresponding with the beginning of the wet season and end of the dry season,
respectively.
Historical vegetation data were referenced from management agency studies
conducted in 1956, eight years prior to water regulation (Sincock et al. 1957), and in
1971, seven years after (Holcomb and Wegener 1971). These studies used intercept
methods to calculate frequency of occurrence along transects perpendicular to shore,
with several locations overlapping the sites in this study. These methods vary
considerably from the sample techniques used here but are the only estimates of
dominant species and their distributions along shoreline elevations prior to stage
regulation. While not specifically referenced as restoration targets by managers, these
early data served as representatives of the pre-stabilization, pre-nutrient pollution,
sandy substrate communities that were often invoked by proponents of this project.
Analyses
Pre/post-restoration comparison
To determine vegetation responses to the 2004 muck removal project, plant
species density and biomass were summed in each quadrat from December 2002 and
69
June 2003 to represent pre-restoration communities, and December 2007 and June
2008 samples as post-restoration representatives. Importance Values (IV) were
computed from these summed values by averaging the relative biomass and density of
each species in each quadrat, and converting to a percentage value.
IV = (Relative Biomass + Relative Density)/2 *100
Importance values were used to estimate species importance within a given
quadrat as they are not biased towards large, few-stemmed species or small,
numerous-stemmed species. This calculation also relativized the dataset, eliminating
the need for transformations typically applied to density or biomass data that can vary
by orders of magnitude between species and samples (McCune and Grace 2002).
To reduce noise from rare species, only those with cumulative IV’s composing
95% of the total were retained for this analysis. Many studies eliminate species that
occur in less than 1–5% of samples, but I used 5% of the total IV instead. This method
was more representative of the actual importance of a species throughout the sample
for the same reason IV’s are more representative of a species’ abundance than
frequency. Analyses were limited to more common species as the dominant community
responses to treatment were of primary interest, and not necessarily the loss or addition
of rare species. Final matrices consisted of 72 samples by 18 species for the pre- and
post-enhancement periods, reduced from the 37 species encountered over the four
combined sample periods. All analyses for the pre-post comparisons were performed
on these matrices and unless otherwise specified, performed using PCORD software
(McCune and Mefford 1999).
70
A hierarchical, agglomerative Cluster Analysis was used to find groups of similar
species compositions, termed here as communities. Flexible beta (-0.25) linkage and
Sorenson distance measures were chosen for their space conserving properties,
compatibilities with each other, and their advantages with non-normal data (McCune
and Grace 2002). This analysis grouped similar sample units based on species IV’s,
using multiple species as a basis for deciding on the fusion of additional groups.
An Indicator Species Analysis (ISA) was performed for two reasons: 1) to
determine the optimum number of clusters for further analysis and 2) to define those
clusters in terms of representative species. This analysis uses the proportional IV and
frequency of a particular species in a particular cluster relative to its IV and frequency in
all other clusters (Dufrene and Legendre 1997). The optimum number of clusters was
determined by the level of clustering that produced the most species with p-values
< 0.05 in the indicator species analysis (McCune and Grace 2002). Species with low p-
values (< 0.05) and high indicator values (> 50) were used as community descriptors
(cluster labels) in future analyses.
A Classification and Regression Tree (CART) model (S-Plus Tree Library, De’ath
2002) was used to classify samples into the groups identified by the cluster analysis
using measured environmental variables alone. The Gini index was used to measure
impurity (Breiman et al. 1984), cross-validation to select the best tree size (Vayssieres
et al. 2000), and 1-Standard Error as an estimate of variation explained by the model
(De'ath 2002). By building CART models for pre- and post-enhancement communities,
species distributions could be compared across environmental, spatial, treatment, and
temporal gradients. Several combinations of the variables water depth, soil organic
71
content, and bulk density were used as continuous predictors, while site, treatment, and
whether the sample occurred on a floating mat were used as categorical variables.
Temporal analyses
In order to track changes in species biomass over time, I combined sub-samples
within each depth class and site by treatment and sample occasion, resulting in six
samples over 13 time periods, each representing a depth class and treatment in a site.
Nonmetric Multi-dimensional Scaling (NMS) ordinations were run for each site to
graphically display changes in species abundances throughout the period of study
(McCune and Grace 2002). Joint plots of correlated variables (R2 > 0.20) were
overlayed onto the ordination diagrams, with length and direction representative of their
correlation to the axes. The sample units were color coded by treatment and
consecutive samples were connected by vectors to track their movements. Within each
site, ordinations were graphically separated by depth class for ease of interpretation.
Results
Soils
Soil percent organic matter was plotted by treatment and time period, i.e. before
and after the lake restoration project, using all subsamples and depth stratifications
(Figure 3-2). The mean percent organic was 33% across all samples prior to treatment,
and the median was 11%. After muck removal, the mean and median of scraped plots
were both less than 2%, and were 15% and 4%, respectively, in the control plots. After
averaging across all subsamples (resulting in n = 6), Wilcoxon signed rank tests showed
significant differences between the pre- and post-enhancement periods in both the
control (P = 0.031) and the treatment plots (P = 0.016) at the 0.05 alpha level.
However, I was unable to detect a significant difference between treatments in the
72
amount of percent organic matter lost after restoration, using a Wilcoxon rank sum test
(P = 0.09). The amount of organic material lost was more variable in the control sites,
but not significantly less overall than the treated areas.
Figure 3-2. A boxplot of percent organic content in all soil cores from treatment and control plots, before (2002) and after (2008) the dry-down and muck removal project (before averaging sub-samples). Shaded boxes represent the 25th and 75th percentiles, whisker bars are the 10th and 90th percentiles, and solid circles are outliers. The means (dashed lines) and medians (solid lines) are shown within each shaded box.
Vegetation
Species richness was lowest in the shallowest depth class prior to treatment, with
the second and third depth class having more species in both the control and treated
plots. After the dry-down and scraping, however, both plots reversed patterns and had
more species in the shallowest depth class than in the deepest (Figure 3-3).
73
0
5
10
15
20
25
2 3 4 2 3 4
Pre-treatmentPost-treatment
Control Treatment
Water Depth (cm)
# of
Spe
cies
35-68 69-102 103-135 35-68 69-102 103-135
0
5
10
15
20
25
2 3 4 2 3 4
Pre-treatmentPost-treatment
Control Treatment
Water Depth (cm)
# of
Spe
cies
35-68 69-102 103-135 35-68 69-102 103-135
Figure 3-3. Species richness by depth category and treatment, before and after restoration.
Changes in biomass after treatment application were tallied for several of the most
common species (Table 3-1). These tallies were indicative of total change, including all
depth, site, and subsamples for each treatment type. Several species had substantial
declines in biomass regardless of treatment, including Pontederia cordata and water
lilies (Nuphar advena, Nymphaea odorata, and Nymphoides aquatica). Species that
had substantial increases in biomass in control plots included Luziola fluitans,
Polygonum hydropiperoides, Hydrilla verticillata, and Vallisneria americana. The few
species that benefited from the mechanical scraping were Vallisneria, Panicum repens,
Hydrilla, and Eleocharis spp. Vallisneria was not recorded prior to the treatment, and
74
had over 1.3 kg (dry weight) totaled across the last two sample periods. P. repens had
a 29% increase in biomass in scraped plots, vs. a 35% decrease in controls.
Table 3-1. Change in total dry biomass (g) from two pre- and two post-treatment sample periods of common species. Percent change could not be calculated if no biomass was recorded before treatment.
Control Treat
Species Biomass (g) % Change Biomass (g) % Change
P. cordata - 3356 - 66% - 3966 - 83%L. fluitans 1037 124% - 171 - 83%Water lilies - 350 - 72% - 150 - 82%P. hydropip. 520 522% - 32 - 97%P. geminatum 16 23% 45 500%Eleocharis spp. 63 112% 200 1100%H. verticillata 497 43% 320 68%P. repens - 84 - 35% 320 29%V. americana 270 N/A 1316 N/A
Time Series
The NMS ordinations tracking species biomass through time suggested varying
stages of recovery depending on depth and site. Treatment effects were evident when
the end point of the control and treatment trajectories were 1) in different locations
relative to each other, indicating different compositions between treatments, and 2)
when the treatment trajectory was stabilized in a different species space at the end of
the study (new community established), and the control trajectory was near its origin
(recovery in control plots).
Pearson correlations were calculated for each environmental variable and axis,
and those with R2 > 0.20 were displayed on the two axes with the highest amount of
variance explained in the three dimensional solution (McCune and Mefford 1999). Axes
had at least a weak correlation to either soil organic matter, water depth, or both in all
75
ordinations. These correlations were portrayed with a red arrow next to the
corresponding axis, with directionality indicating increasing values of organic matter
percentage or water depth. The three depth figures for each site were separated from
one ordination to ease interpretation.
The ordinations for Site 1 suggest the shallowest depth class control (dashed
lines) and treatment (solid lines) plots had recovered to near pre-treatment
compositions by the end of the study, as evidenced by the proximity of the beginning
and end points of the arrow trajectories (Figure 3-4). The treatment plot in the second
depth class (69–102 cm), however, actually appeared to be closer to the 2003
compositions than the control plot did, indicating further recovery in the treated area.
The deepest samples at this site appeared to show less change overall and also
seemed to be near the pre-treatment conditions in both control and treated plots.
Site 2 ordinations suggested substantial recovery in the shallowest depth class,
again with no striking difference in either trajectories or degree of recovery between
treatments (Figure 3-4). The second depth class at this site, however, had a different
composition in the treated plots by the end of the study, and an apparent recovery in the
control plots. Both plots seemed to have stable communities, with very little distance
(dissimilarity) between the last two sample periods. This was indicative of a strong
treatment effect. Both the treatment and control plots remained different from pre-
treatment conditions in the deepest class, though the last sample in the control plot
indicated recovery may be taking place as it moved nearer its origin.
76
Site1
Site 2
Site 3
Depth 35-68 cm (2ft) 69-102 cm (3ft) 102-135 cm (4ft)Ax
is 2
Figure 3-4. NMS ordinations of each site, with depth categories graphically separated. Dashed lines show control plot trajectories and solid lines indicate treated plots. Axes 1 and 2 are horizontal and vertical, respectively, for all of the graphs. Site 1: Water depth weakly negatively correlated with Axis 2 (R2 -0.34) while soil percent organic matter positively correlated (R2 0.21). Site 2: Percent organic negatively correlated with Axis 1 (R2 -0.32). Site 3: Percent organic negatively correlated with Axis 1 (R2 -0.48).
Site 3 had similar patterns, with the shallowest samples having recovered in both
the control and treated plots, while the second depth class showed a remarkable
difference in recovery between the treatments (Figure 3-4). The scraped plot at this
depth remained very dissimilar in terms of species composition and biomass than it was
prior to treatment, while the control plot had recovered. Again, this was indicative of a
strong treatment effect. The deepest samples, however, showed substantially different
communities in treatment and control plots, indicating both areas remained
77
compositionally changed after restoration, regardless of whether or not they were
mechanically scraped.
Community Changes
The four samples from the pre- (December 2002 and June 2003) and post-
treatment (Dec 2007 and Jun 2008) periods had 37 species, 18 of which comprised the
top 95% of the cumulative importance values. The pre- and post-treatment summed
datasets resulted in matrices of 72 samples by 18 species, which were divided into six
communities (clusters) for the pre- (3.5% chaining, 55% information remaining) and
post-restoration (2.6% chaining, 55% information remaining) periods. Species with
indicator values of approximately 50 or greater from the ISA were used to define
clusters as community states (Table 3-2), and were labeled accordingly. The pre-
restoration indicators were: 1) Luziola fluitans and Panicum repens, 2) Pontederia
cordata and Alternanthera philoxeroides, 3) Hydrocotyle spp., 4) Hydrilla verticillata, 5)
Lymnobium spongia and Eichhornia crassipes, and 6) Utricularia spp., Nuphar advena,
and Nymphaea odorata.
The post-treatment period also had six communities identified by the cluster and
ISA, which were 1) Eleocharis spp. and P. repens, 2) Luziola, Polygonum, and
Paspalidium acuminatum, 3) Pontederia, 4) Typha spp. and Nuphar, 5) Hydrilla, and 6)
Vallisneria (Table 3-3).
78
Table 3-2. Indicator values of species in the pre-enhancement period (Dec 2002, Jun 2003), with values ranging 0–100.
P_value Species Group 1 2 3 4 5 6
0.001 EICCR 49 0 0 0 0 0 0.000 LYMSP 63 0 1 2 0 0 0.000 LUZFL 0 98 0 0 0 0 0.007 PANRE 2 46 0 0 4 0 0.000 HYDSP 7 0 57 0 0 0 0.000 HYDVE 3 0 1 88 0 0 0.000 PONCO 1 11 28 0 53 0 0.001 ALTPH 3 11 13 0 46 0 0.000 UTRSP 0 0 0 0 0 94 0.001 NUPAD 0 0 0 0 0 64 0.000 NYMOD 0 0 0 0 0 48 0.697 POLHY 9 0 4 0 7 0 0.170 UNPAS 11 21 0 0 5 0 0.044 CERSP 1 0 0 20 0 32 0.047 PANHE 0 0 0 0 0 31 0.090 SAGLN 0 0 21 0 0 0 0.229 TYPSP 0 0 14 0 1 0 0.010 ELESP 0 36 0 0 0 0
Species with high indicator values are highlighted accordingly and are used as community descriptors for each group.
79
Table 3-3. Indicator values of species in the post-enhancement period (Dec 2007, Jun 2008), with values ranging 0–100.
P_value Species Group 1 2 3 4 5 6
0.000 LUZFL 76 0 0 13 3 0 0.000 POLHY 63 0 0 3 3 0 0.000 PASAC 61 0 0 10 4 0 0.000 VALAM 0 92 3 0 0 0 0.000 HYDVE 0 5 75 0 0 9 0.000 PANRE 5 0 0 68 2 0 0.000 ELESP 4 0 1 61 9 0 0.000 PONCO 1 0 0 1 89 1 0.006 TYPSP 0 0 0 0 0 40 0.016 NUPAD 0 0 2 0 0 37 0.183 ALTPH 22 0 0 14 19 1 0.068 HYDSP 0 2 0 25 4 0 0.039 SAGLN 0 0 0 0 25 0 0.302 PANHE 4 0 0 0 11 0 0.456 CERSP 0 0 10 0 0 0 0.844 NYMOD 0 4 1 0 0 0 0.241 CHASP 0 5 16 0 0 0 0.301 UTRSP 3 0 13 0 1 0
Species with high indicator values are highlighted accordingly and are used as community descriptors for each group.
Five of the six communities were predicted by water depth, soil percent organic
matter, site location, and whether the sample was categorized as a floating mat (Figure
3-5). The Eichhornia and Lymnobium community identified by the cluster and ISA
analyses was not delineated at this level of pruning, and only contained 3 of the 72
samples in the analysis.
80
HYDVE(9)
HYDSP(7)
UTRSP_NUPAD_NYMOD(5)
LUZFL_PANRE(9)
PONCO_ALTPH(42)
Water depth > 109 cm
Site 1
Organic < 50%
Water > 58 cmSites 2 & 3
HYDVE(9)
HYDSP(7)
UTRSP_NUPAD_NYMOD(5)
LUZFL_PANRE(9)
PONCO_ALTPH(42)
HYDSPHYDVELUZFL_PANRELYMSP_EICCRPONCO_ALTPHUTRSP_NUPAD_NYMOD
HYDSPHYDVELUZFL_PANRELYMSP_EICCRPONCO_ALTPHUTRSP_NUPAD_NYMOD
HYDSPHYDVELUZFL_PANRELYMSP_EICCRPONCO_ALTPHUTRSP_NUPAD_NYMOD
Missclass rate : Model = 0.28 Error : 0.49
Figure 3-5. CART model of pre-treatment community distribution along the measured environmental gradients. The numbers of samples in each leaf are shown in parentheses below bargraphs, which show the compositions of communities within each leaf. Species abbreviations are the first three letters of genus and first two of specific epithet (PONCO = Pontederia cordata).
The biggest difference in community types occurred at 109 cm in water depth.
The most abundant community of the pre-treatment period was Pontederia and
Alternanthera, with 58% of all samples classified as such. This community was
predicted to occur in 58–109 cm of water depth at full pool, and represented the habitat
type targeted by restoration efforts. The shallowest community was Luziola and P.
repens, occurring at < 58 cm. Deeper communities differed primarily by site. The
Hydrilla community dominated at Site 1 at > 109 cm in water depth, while Site 2 and 3
had a Hydrocotyle community, or Utricularia, Nuphar, and Nymphaea. The Hydrocotyle
81
community was indicative of a floating mat, or tussock, as evidenced by the high soil
organic content (> 50%) and the fact that Hydrocotyle cannot survive in > 109 cm in
water without a buoyant substrate.
The best CART model for the post-treatment period was pruned to seven leaves,
with five of the six communities again represented (Figure 3-6). The misclassification
rate was 33%, with 53% of the variation explained (1-Standard Error). Soil percent
organic matter was omitted from the final model, primarily to ease interpretation of
treatment effects. When soil organic matter was included, several tree splits were
attributed to soil differences, rather than treatment type. The soil differences were
directly related to whether or not samples were treated, and the final groups only varied
by three samples between models. I chose the model without soils type included so as
to emphasize the difference in treatment type rather than having to infer treatment from
soil organic matter content.
Contrary to the pre-treatment period, the main break between community types in
the post period occurred at 69 cm in water depth, rather than 109 cm. The majority of
samples in the post period were identified as Hydrilla rather than Pontederia, with all
control samples at > 69 cm in water depth classified as such. The treated sites varied
between Vallisneria or Hydrilla at > 69 cm in depth.
The Pontederia group that was so prominent in the pre-treatment period was
reduced to 8 samples in the post period, down from 58, and no longer had
Alternanthera as a co-indicator. This community was classified in both treated and
control areas, but was restricted to a very narrow water depth, occurring at 61–69 cm.
There were also treatment differences in the shallowest samples, with control plots
82
having Luziola, Polygonum, and P. acuminatum. at < 61 cm in water depth, while
treated plots had an Eleocharis community at < 66 cm.
Water depth > 69 cm
Treatment
Water < 66 cmSite 3
Control
Water > 61 cmSites 1 & 2
ELESP(7)
PONCO(3)
LUZFL_POLHY_PASSP(9) PONCO
(5)
HYDVE(22)
HYDVE(9)
VALAM(17)
TreatmentControl
ELESP(7)
PONCO(3)
LUZFL_POLHY_PASSP(9) PONCO
(5)
HYDVE(22)
HYDVE(9)
VALAM(17)
ELESPHYDVELUZFL_POLHY_PASACPONCOTYPSP_NUPADVALAM
ELESPHYDVE
PONCOTYPSP_NUPADVALAM
ELESPHYDVELUZFL_POLHY_PASPONCOTYPSP_NUPADVALAM
Missclass rate : Model = 0.33 Error : 0.47
Water depth < 69 cm Water depth > 69 cm
Treatment
Water < 66 cmSite 3
Control
Water > 61 cmSites 1 & 2
ELESP(7)
PONCO(3)
LUZFL_POLHY_PASSP(9) PONCO
(5)
HYDVE(22)
HYDVE(9)
VALAM(17)
TreatmentControl
ELESP(7)
PONCO(3)
LUZFL_POLHY_PASSP(9) PONCO
(5)
HYDVE(22)
HYDVE(9)
VALAM(17)
ELESPHYDVELUZFL_POLHY_PASACPONCOTYPSP_NUPADVALAM
ELESPHYDVELUZFL_POLHY_PASACPONCOTYPSP_NUPADVALAM
ELESPHYDVE
PONCOTYPSP_NUPADVALAM
ELESPHYDVELUZFL_POLHY_PASPONCOTYPSP_NUPADVALAM
Missclass rate : Model = 0.33 Error : 0.47
Water depth < 69 cm
Figure 3-6. CART model of post-treatment community distribution along the measured environmental gradients. The numbers of samples in each leaf are shown in parentheses below each bargraph, which shows the compositions of communities within each leaf. Species abbreviations are the first three letters of genus and first two of specific epithet (PONCO = Pontederia cordata).
Discussion
Muck Removal
This project is the first to document littoral vegetation community responses to a
mechanical muck removal project, particularly one of this scale. Previous studies have
83
monitored short-term (two years) changes in species frequencies in treated areas
(Moyer et al. 1989), but this paper details vegetation community responses over a
longer time frame (four years), establishes recovery rates, and showed how treatment
effects vary by water depth. In as little as four years after restoration, I documented that
submersed vegetation had replaced dense emergent and floating leaf communities in
treated areas, and that the newly established communities showed signs of
stabilization, evidenced by smaller changes in community composition between sample
periods.
The primary community in the zone targeted for restoration was Pontederia, which
dominated littoral environments in roughly 30–122 cm in depth prior to treatment.
Typha stands were scattered at the deeper edge of the Pontederia community, and both
of these species have been considered to support low diversity, monocultural stands
that rapidly accumulate leaf litter, or organic sediment (Hoyer and Canfield 1997).
Interestingly, this study found no consistent change in species richness after the
treatment, and an actual decrease in the total number of species encountered from 32
to 27. This was primarily due to a loss of rare species or those associated with floating
mats of vegetation (Eupatorium spp, Bidens laevis, Scirpus cubensis), which have been
shown to increase species richness in wetlands by providing variably inundated
substrates (Cherry and Gough 2006).
Water lilies (Nuphar, Nymphaea) were not specifically targeted by the mechanical
scraping, but they were largely absent following the several month drawdown,
presumably due to drought intolerance. These species and Typha are known to be
susceptible to periodic drying events (Li et al. 2004, David 1996), and may rebound if
84
water depths remain similar to pre-treatment levels for a long enough period of time.
While not evident here, some populations of water lilies were established by the end of
the study outside of sampled areas.
The three communities most affected by the restoration project, Pontederia,
Typha, and water lilies, were completely replaced by submersed communities in all but
the shallowest of treated areas. Four years after restoration, Vallisneria and Hydrilla
dominated the deeper scraped sites, with Vallisneria forming dense carpets (an average
of 634 plants per square meter) on the sandy substrates. This species was present
prior to muck removal but was infrequent (Sincock et al. 1957, Moyer et al. 1989),
raising concerns about whether its rebound will be limited and if it will be out-competed
under sustained pre-restoration hydrologic conditions.
In the shallowest of the study areas, a grassy community dominated by the exotic
species P. repens replaced Pontederia, which resulted in a more similar shoreline to
what was described in the 1950's (Sincock et al. 1957). During that period, water levels
fluctuated more than two meters during some years, and these large oscillations likely
favored the highly invasive exotic, P. repens. This species frequently invades disturbed
shorelines, and has become problematic in many of Florida's water bodies (Schardt
1997, Smith et al. 2004). The mechanical and drawdown disturbances caused by this
restoration project increased P. repens biomasses by 140% over a four year period, and
expanded its distribution from < 65 cm to < 98 cm in water depth. Future drawdowns or
regional droughts might extend the lakeward range of P. repens further, which is known
to expand during droughts and can tolerate flooding depths > 1m when established
(Smith et al. 2004).
85
Overall, muck removal treatments were most effective in deeper-water
communities (70–130 cm), and had longer-lasting impacts on dense emergent or
floating mat communities than submersed. For example, emergent species like
Pontederia that may have been dependent on buoyant, organic mats to survive at these
depths will take longer to re-establish than submersed species, and no such recoveries
were documented after four years in this study. Control plots were also slow to recover
at these depths, but several plots had regained similar species compositions and
biomasses within four years of drawdown. The shallowest areas (35–68 cm) studied,
however, showed temporary treatment effects at best, with dense emergent
communities recovering within three years after muck removal.
Management Implications
Mechanical muck removal is used as a method of setting back soil or shoreline
succession; by removing organic substrates and associated nutrients, re-establishing
sparse communities of macrophytes, and essentially creating a habitat more indicative
of high disturbance conditions. This technique has been used to restore other
peatlands where accumulated organics have raised nutrient levels and resulted in
losses of diversity (Jacquemart et al. 2003). However, in a lake the size of
Tohopekaliga, mechanically removing soils and associated plant communities from
1500 ha of shoreline may not realistically change nutrient concentrations. Half of the
seven million cubic meters of material scraped from Toho was redeposited directly
within the lake on spoil islands, and water column nutrient levels were unchanged two
years after treatment (Hoyer et al. 2008).
In reality, muck removal projects on shallow, eutrophic lakes are likely to cause
shifts in the compositions or distributions of dominant vegetation types (at least
86
temporarily), rather than lower littoral productivity or nutrient concentrations. In order to
maintain a diversity of vegetation types and limit the eventual reformation of floating
tussock communities, changes in lake stage regulations must be considered. Keddy
and Fraser (2000) suggested introducing inter-annual variability in water schedules to
maximize shoreline diversity, which would more closely mimic historical conditions on
Lake Toho. Even though shoreline developments have lowered the maximum allowable
lake stages by almost one meter, incorporating a half-meter of variability between water
years might increase the littoral diversity. Generally, lakes with high fertility and low
levels of disturbance (stable, predictable water schedules) are dominated by low
diversity littoral zones, supporting large stands of nearly monocultural, highly
competitive species (Grime 1979), like Pontederia. Shoreline diversity can be increased
by either lowering fertility or increasing disturbance events, the latter of which could be
accomplished through inter-annual stage fluctuations. Point-source pollution was
eliminated on Lake Toho in the late 1980's (James et al. 1994), and further reductions in
fertility would likely involve addressing non-point source runoff through watershed
changes; an extremely difficult task in an urbanized and agricultural landscape.
Disturbance related to flooding and drying of littoral communities remains a viable tool in
managing shoreline vegetation, and may reduce the need for such large-scale,
intensive management projects in the future.
Before applying the results of this project to other large, shallow lakes where muck
removal is being considered, several caveats should be addressed. Lake Toho has a
significant population of the submersed exotic species Hydrilla in deeper areas of the
littoral zone, beyond the depths sampled in this study. Without submersed species
87
stabilizing deeper sediments, drawdowns might increase wind-induced turbulence of the
lake bottom; releasing nutrients, decreasing water clarity, and perhaps limiting
macrophyte establishment even upon reflooding (Blindow et al 1993). If a large lake
already has unconsolidated sediments and deep-water portions that do not support
submersed vegetation, low water levels and the removal of shoreline vegetation may
cause a shift to a phytoplankton-dominated state (Scheffer et al. 1993). Lake Toho had
the lowest amount of submersed vegetation since the 1980’s (BIPM 2005) immediately
following this restoration, and lower water quality measures for nearly two years. These
changes were attributed to tropical disturbances during the reflooding phase of
treatment, another caveat in the application of these results to other systems (Ch. 4).
Several conditions will likely affect the outcome of mechanical muck removal projects,
including lake size, water depth, maximum fetch, nutrient concentrations, and sediment
stability, any of which may affect water quality/turbidity and vegetation establishment in
treated areas.
Finally, water levels after treatment should be a major focus by management
agencies, as hydrology is the primary factor in determining wetland and littoral
vegetation (Pearsal 1920, Walker and Coupland 1968, van der Valk and Welling 1988).
The treatments in this study were immediately followed by the passing of three major
hurricanes, which resulted in high water events for several months following muck
removal. Had lake levels risen at a slower rate or oscillated during the early recovery
period, entirely different communities may have been established in treated areas (van
der Valk 1981). In the case of this study, short-term responses were positive (though
different than expected) in that the dense, robust communities that dominated the
88
shallow littoral zone for over 20 years were replaced with Vallisneria, an important
species for waterfowl (McAtee 1939, Sculthorpe 1967) and sportfish (Barnett and
Schneider 1974), and which allows for better recreational access. Longer-term
monitoring is needed in order to asses the persistence or longevity of these treatment
effects.
89
CHAPTER 4 HURRICANE EFFECTS ON A LARGE-SCALE LITTORAL HABITAT RESTORATION
PROJECT
Introduction
The importance of water levels in regulating wetland and littoral vegetation
communities has long been recognized (Pearsall 1920, Segal 1971). Hydrology is
typically the strongest environmental factor controlling wetland plant community
composition (Walker and Coupland 1968, van der Valk and Welling 1988), through
influencing seed viability (Poiani and Johnson 1989), recruitment (Seabloom et al.
1998), and the growth and survival of adult plants (Squires and van der Valk 1992).
The frequency, duration, and seasonality of flooding are therefore critical processes in
determining wetland and littoral plant communities (Gasith and Gafny 1990, Keddy
1983), affecting specific diversity and structural complexity of vegetation (Wilson and
Keddy 1988, Wilcox and Meeker 1991).
Lake and wetland managers have used water levels to manipulate vegetation
communities for decades (e.g. Wegener 1974), but hydrologic schedules are often
regulated by anthropogenic needs (flood control, water supply) before ecological effects
are considered (Havens and Gawlik 2005). In many temperate reservoir lakes, water
levels fluctuate too widely and reduce shoreline diversity, often resulting in unvegetated
portions of littoral zone (Hill et al. 1998). In Florida, USA, where many lakes are used
for flood control and water supply purposes, water levels can be stabilized from their
natural range and often have higher nutrient concentrations as well. A general
decrease in specific diversity or structural complexity of communities after water-level
stabilization (Keddy 1983) or eutrophication (Seddon 1972, Lachavanne 1985, Harper
1992) has been well documented, and such degradation is often countered with
90
periodic, infrequent drawdowns in hopes of reestablishing desirable submersed or
emergent vegetation communities (Wegener 1974, Havens 2004). Some lakes, most
recently and notably Lake Tohopekaliga (hereafter Lake Toho) in central Florida, also
have organic sediments and associated vegetation mechanically removed during the
drawdown period to aid colonization of desirable species in the absence of competitive
dominants (FFWCC 2003). While this effort on Toho was successful in establishing a
previously undocumented, novel community in treated areas (see Ch’s 2 and 3), the
results may have been largely influenced by natural hydrological events following the
multi-million dollar project.
Immediately after muck removal was completed and the lake began to fill, three
major hurricanes passed within 65 kilometers of Toho, raising water levels 2.5 meters
over a four month period to the highest lake stage since 1960 (0.5 m above maximum
pool). This prolonged and deep flooding event on the heels of the restoration project
likely affected early colonization and subsequent succession in treated areas. For
example, without abiotic stressors (e.g. flooding), community composition is determined
by dispersal and colonization events (Seabloom et al. 1988), and the order of species
arrival at sites has been shown to affect species distributions for some time (Tilman
1997, Grace 1987). If the rate, depth, and duration of flooding caused by hurricanes
was sufficient to regulate or even eliminate early colonizers, initial succession would
have occurred after normal lake stages were restored, which may have favored the
originally established communities that were removed during restoration. Without any
knowledge of how these hurricanes may have affected succession and the overall
outcome of this project, it would be difficult to apply these results to other projects on
91
similar lakes. The goal of this paper was to determine the impacts that natural
disturbances may have had on this intensive restoration effort. Specifically, I asked: 1)
Whether initial colonization compositions differed from those after the hurricanes, and 2)
Whether the eventual dominant species were a result of the high-water events. These
results are important for managers to understand the efficacy of this relatively new
restoration approach, and serve as an important reminder that outcomes of large-scale
projects may depend heavily on uncontrollable, external influences.
Methods
Mechanical muck removal began in late spring of 2004 after water levels reached
a low of 14.9 m (NGVD), or approximately 1.0 m below normal low pool stage. The
project was completed by June 2004, at which point water depths were slowly increased
to regular stage levels. Standing, above ground, vegetation biomass and stem density
measurements were collected from 0.25 m2 quadrats in late August 2004, December
2004, and in the summer and winter of each year after until June 2008. Samples were
collected late in the summer of 2004 (August), anticipating water levels would be near
normal lake stages and initial succession or colonization would have taken place in
scraped areas prior to sampling.
One hurricane passed over the lake in mid August (2004), which doubled the rate
of water level rise over the second half of the month and brought the lake close to
maximum stage by the time of the first sample (Figure 4-1). Two more major hurricanes
passed in September and October of 2004, further increasing lake stages to 0.5 m
above full pool, the highest level recorded since 1960. Lake levels remained at or
above maximum stage for seven months, from September 2004 until the end of March
2005. Lake stage data were collected from a South Florida Water Management District
92
gauge located at the south end of the lake (S-61H). Visual assessments of wind/wave
damage were conducted after the last hurricane passed, and other studies documented
changes in water quality (Hoyer et al. 2008).
14.50
15.00
15.50
16.00
16.50
17.00
June 04 Aug 04 Oct 04 Dec 04 Feb 05 Apr 05
Lake
Sta
ge (M
eter
s N
GV
D)
Sample
Hurricanes
Sample
Figure 4-1. Lake stages (meters above sea level NGVD) following the managed dry
down in summer of 2004. Dotted lines indicate normal maximum and minimum lake regulation schedules, and the first two sample periods of early colonizers are depicted on the graph.
Vegetation data were used from two other studies designed to assess littoral
vegetation responses to the muck removal project. They were: 1) an experimental
study where sampling was restricted to water depth zones that were mechanically
scraped, and study sites consisted of treated (scraped) and control (unscraped) plots
(see Ch. 3), and 2) a lake-wide study where sampling occurred throughout the range of
93
emergent littoral zone, including areas too deep for bulldozers to access (145–200 cm)
(see Ch. 2). Sampling methodologies in these studies differed only in that oven-dried
biomasses were recorded in the former and wet biomasses in the latter. Sampling was
stratified by depth category at each site, and several subsamples were collected within
each stratification. Species data were summed across subsamples within each
stratification, and unless otherwise noted, averaged across sites for each time period.
Bare ground (empty) samples were counted individually across all stratifications.
Biannual samples were also collected for two years prior to muck removal.
Hydroperiods were calculated for samples based on the average number of days
flooded per year from 1993 through 2002, a ten year period of hydrologic record
immediately preceding sampling. This period was representative of the typical annual
lake stage regulation schedules, absent artificial dry-downs that occurred in 1987 and
2004.
Results
Dominant species biomasses were averaged across sites for the first four sample
periods following muck removal to evaluate initial site colonization. In the experimental
study sites, Paspalidium geminatum had the highest biomass and stem counts of all
species in treated plots immediately after reflooding in August 2004 (Figure 4-2). Other
prominent species in scraped areas were Pontederia cordata, Panicum repens,
Polygonum hydropiperoides, and Alternanthera philoxeroides. These same species
were recorded in the control sites but with different relative abundances, with
Pontederia, Polygonum, and Alternanthera dominating unscraped sections of shoreline
(Figure 4-3). Following the hurricanes, all biomass was severely reduced in both control
94
and treated plots, and only Pontederia and P. repens had recovered to initial levels in
either plot by the following December (2005).
0
2
4
6
8
10
12
14
1 2 3 4
PASGEPANREPOLHYALTPHPONCO
10
14
12
2
0Aug 04 Dec 04 Jun 05 Dec 05
Ave
rage
Dry
Bio
mas
s (g
)
6
4
8
Figure 4-2. Initial relative abundances of dominant species in scraped experimental plots. Dry biomasses (g) were averaged across water depths and sites for each species. Species were coded as the first three letters of genus and the first two of specific epithet (e.g. ALTPH = Alternanthera philoxeroides).
95
0
5
10
15
20
25
30
35
1 2 3 4
PASGEPANREPOLHYALTPHPONCO
30
35
20
10
0Aug 04 Dec 04 Jun 05 Dec 05
Ave
rage
Dry
Bio
mas
s (g
)
15
5
25
Figure 4-3. Initial relative abundances of dominant species in control (unscraped) experimental plots. Dry biomasses (g) were averaged across water depths and sites for each species. Species were coded as the first three letters of genus and the first two of specific epithet (e.g. PANRE = Panicum repens).
The shallower, scraped sections of the lake-wide study sites responded similarly to
the experimental treatment plots, with original colonizers including P. geminatum and
Pontederia. Other dominant species differed, however, with these sites having Hydrilla
verticillata, Eleocharis spp., and Paspalum acuminatum (Figure 4-4). Following the
hurricanes, there were massive declines in all biomasses, and only Pontederia, P.
geminatum, and Hydrilla had recovered in the scraped areas by the following December
(2005).
96
0
50
100
150
200
250
1 2 3 4
PASACELESPPASGEHYDVEPONCO
100
150
200
50
0Aug 04 Dec 04 Jun 05 Dec 05
Ave
rage
Wet
Bio
mas
s (g
)250
Lost toHigh Water
Figure 4-4. Initial species compositions of dominant species in scraped sections of lake-wide study sites. Wet biomasses (g) were averaged across water depths and sites for each species. Species were coded as the first three letters of genus and the first two of specific epithet (e.g. PASAC = Paspalidium acuminatum).
Total species biomass across all lake-wide sites declined considerably after the
hurricanes as well, particularly in the shallower scraped areas (Figure 4-5). However,
even the deeper-water, unscraped sections of littoral zone had massive losses in
biomass, reaching their lowest levels of the study between June and December of 2005.
97
0 1 2 3 4 5
Average Wet Biomass (kg) per Site
Jun 02
Dec 02
Jun 03
Dec 03
Aug 04
Dec 04
Jun 05
Dec 05
Jun 06
Dec 06
Jun 07
Dec 07
Jun 0810 12
Deep WaterScrapedTreat/RefloodHurricanes
Figure 4-5. Average wet biomass per site (kg) of all species in the shallow, scraped
(gray) and deeper water, unscraped (black) sections of the lake-wide study sites. Standard errors of the means are shown above each bar, and the cessation of treatment and resumption of water levels is indicated in red.
Most species were reduced in biomass either from the mechanical removal or
desiccation during the dry down, except for P. geminatum and P. acuminatum. The
latter increased in biomass and abundance considerably before the hurricanes, though
it was never found at high abundance prior to treatment (Figure 4-6). P. geminatum
was abundant throughout the study, and also had its highest biomass immediately
following treatment. The vast majority of the increased biomass was from deeper-water
areas where mechanical scraping did not occur, where P. geminatum was already well
established (Figure 4-6).
98
Deep WaterScrapedTreat/Reflood
0 0.2 0.6 1.0 1.4
B. Paspalidium geminatum
A. Paspalidium acuminatum
0 10 20 30 40 50 60 70
Jun 02
Dec 02
Jun 03
Dec 03
Aug 04
Dec 04
Jun 05
Dec 05
Jun 06
Dec 06
Jun 07
Dec 07
Jun 08
Jun 02
Dec 02
Jun 03
Dec 03
Aug 04
Dec 04
Jun 05
Dec 05
Jun 06
Dec 06
Jun 07
Dec 07
Jun 08
Hurricanes
Deep WaterScrapedTreat/Reflood
0 0.2 0.6 1.0 1.4
B. Paspalidium geminatum
A. Paspalidium acuminatum
0 10 20 30 40 50 60 70
Jun 02
Dec 02
Jun 03
Dec 03
Aug 04
Dec 04
Jun 05
Dec 05
Jun 06
Dec 06
Jun 07
Dec 07
Jun 08
Jun 02
Dec 02
Jun 03
Dec 03
Aug 04
Dec 04
Jun 05
Dec 05
Jun 06
Dec 06
Jun 07
Dec 07
Jun 08
Hurricanes
Figure 4-6. Average wet biomass per site of A) P. acuminatum (grams) in the shallow, scraped (gray) and deeper water, unscraped (black) sections of the lake-wide study sites, and B) P. geminatum (kilograms). Standard errors of the means are shown above each bar, and the cessation of treatment and resumption of water levels is indicated in red.
99
Following the hurricanes and high water, P. acuminatum was never recorded in
the deeper, unscraped sections of the lake-wide study again, and was only occasionally
found at low levels in the shallower, scraped areas. This species was found in low
abundances both before and after treatment in the scraped sections of experimental
plots, however, and at occasionally higher abundances throughout the study in control
plots (Figure 4-7).
0 2 4 6 8 10 12 14 16
Jun 02
Dec 02
Jun 03
Dec 03
Aug 04
Dec 04
Jun 05
Dec 05
Jun 06
Dec 06
Jun 07
Dec 07
Jun 08
Paspalidium acuminatum
10 12
Treated PlotsControlsTreat/RefloodHurricanes
Figure 4-7. Average dry biomass per site (g) of P. acuminatum in control (gray) and
treated (black) sections of experimental plots. Standard errors of the means are shown above each bar, and the cessation of treatment and resumption of water levels is indicated in red.
P. geminatum lost considerable biomass in the unscraped, deeper-water sections
after the hurricanes, essentially all that was gained during the brief dry down. Biomass
remained very similar to pre-treatment levels throughout the study period, however. In
100
the shallower, scraped sections, P. geminatum was at higher levels by the end of the
study than occurred pre-treatment, but still well below its deep water populations.
The only species that was not recorded after initial colonization in the scraped
plots of experimental study sites was Polygonum hydropiperoides, though its biomass
increased in the control plots. All other species that initially colonized the treated plots
were found later in the study period. Polygonum was found throughout the study in the
shallower, scraped sections of lake-wide sites.
The number of empty samples (no species) increased dramatically after the
hurricanes in all sites, including the control plots in the experimental study (Figure 4-8).
Generally, the number of empty quadrats was low in all control and treated plots in
August 2004, even though scraping had occurred and the lake had been reflooded.
Following high water and two additional hurricanes, however, the number of empty
samples increased in all sites and depth zones, including the controls. Empty quadrats
reached a high in all study areas roughly one year after the hurricanes (December
2005), with the exception of the 102–135 cm depth zone in experimental plots. Both the
treated and control plots had the highest number of un-occupied samples in June of
2006, (83% and 67% respectively) two years after treatment.
101
0 2 4 6 8 10 120 2 4 6 8 10 12
Jun 02
Jun 03
Aug 04
Jun 05
Jun 06
Jun 07
Jun 08
35-68 cm (2 ft) n = 12 69-102 cm (3 ft)
102-135 cm (4 ft)
0 2 4 6 8 0 5 10 15 20 25 30 35 40
Scraped Lake-Wide Samples n = 42
Jun 02
Jun 03
Aug 04
Jun 05
Jun 06
Jun 07
Jun 08
10 12
Treated PlotsControlsTreat/RefloodHurricanes
Figure 4-8. Number of empty samples in experimental plots (gray and black) and lake-
wide study sites. Cessation of treatment and resumption of normal water levels are indicated in red.
Re-colonization of scraped areas (after hurricanes) in the lake-wide study
generally did not take place until after December 2006, more than two years after muck
removal was completed. Total biomass of all dominant species increased dramatically
beginning in June 2007, as did Vallisneria americana (Figure 4-9), the eventual
dominant species in all scraped areas of the lake (Ch’s 2 and 3). Together with Hydrilla
and P. repens, these three species comprised 70–80% of the dominant species' total
biomass from June 2007 through June 2008 (Figure 4-10) in treated areas, with
P. geminatum and Pontederia rounding out the main dominants.
102
15.50
16.00
16.50
17.00
17.50
6/1/04 12/1/04 6/1/05 12/1/05 6/1/06 12/1/06 6/1/07 12/1/07 6/1/08Dec 04 Dec 05 Dec 06 Dec 07Jun 07Jun 06Jun 05
Lake
Sta
ge (M
eter
s N
GV
D) Total B
iomass (kg)
# 6 7 8 109 11 12 13
2
4
6
8
10
12
14
16
18A
1
2
3
4
5
6
7
015.50
16.00
16.50
17.00
17.50
6/1/04 12/1/04 6/1/05 12/1/05 6/1/06 12/1/06 6/1/07 12/1/07 6/1/08Dec 04 Dec 05 Dec 06 Dec 07Jun 07Jun 06Jun 05
Lake
Sta
ge (M
eter
s N
GV
D) V
allisneriaB
iomass (kg)
# 6 7 8 109 11 12 13
B
Figure 4-9. Average daily lake stage (meters NGVD) with horizontal dashed lines
representing normal maximum and minimum lake stages. A) Total wet biomass (kg) of all species shown in dashed black line for each sample event B) Vallisneria americana biomass (kg) shown as red dashed line.
103
0
100
200
300
400
500
600
700
800
900
1000
1 2 3 4
PASGEVALAMPANREHYDVEPONCO
800
1000
400
200
0Dec 06 Jun 07 Dec 07 Jun 08
Ave
rage
Wet
Bio
mas
s (g
)
600
Figure 4-10. Average wet biomass (g) of the five dominant species at the end of the study in the lake-wide sites. Species were coded as the first three letters of genus and the first two of specific epithet (e.g. PASGE = Paspalidium geminatum).
Compositions in the experimental plots were very similar to the lake-wide sites by
the end of the study, dominated by Vallisneria, P. repens, Hydrilla, and Pontederia,
though Eleocharis. replaced P. geminatum in the top five at these sites (Figure 4-11).
The control plots were quite different, with Pontederia and Hydrilla sharing dominance
with Typha, Luziola fluitans, and Polygonum (Figure 4-11).
104
0
20
40
60
80
100
120
1 2 3 4
ELESPVALAMPANREHYDVEPONCO
A
80
100
40
20
0Dec 06 Jun 07 Dec 07 Jun 08
60
Ave
rage
Dry
Bio
mas
s (g
)
120
0
20
40
60
80
100
120
140
160
180
200
1 2 3 4
TYPSPLUZFLPOLHYHYDVEPONCO
B
120
160
80
40
0Dec 06 Jun 07 Dec07 Jun 08
Ave
rage
Dry
Bio
mas
s (g
)
40
200
Figure 4-11. Average dry biomass (g) of the five dominant species at the end of the
study in the A) treated plots and B) control plots of the experimental study sites. Species were coded as the first three letters of genus and the first two of specific epithet (e.g. ELESP = Eleocharis spp.).
105
The average number of Vallisneria plants per square meter during the last sample
period was plotted against corresponding hydroperiods for various depth categories of
samples. These hydroperiods were calculated based on the 10 year period of record
from 1993 to 2002. Assuming lake stages return to the same schedule adhered to prior
to restoration, the majority of the depths Vallisneria was found in would be flooded less
than 95% of the year (Figure 4-12).
200
400
600
800
1000
1200
Plants/m2Hydroperiod
0
1200
200
400
1000
600
800
60-75 76-91 92-107 108-122 123-137 138-152 153-168 169-1850
10
20
30
40
50
60
70
80
90
100
Val
lisne
riaP
lant
s pe
r m2
Water depth at Full Pool (cm)
Average A
nnual Hydroperiod (1993-2002)200
400
600
800
1000
1200
Plants/m2HydroperiodPlants/m2Hydroperiod
0
1200
200
400
1000
600
800
60-75 76-91 92-107 108-122 123-137 138-152 153-168 169-1850
10
20
30
40
50
60
70
80
90
100
Val
lisne
riaP
lant
s pe
r m2
Water depth at Full Pool (cm)
Average A
nnual Hydroperiod (1993-2002)
Figure 4-12. Average number of Vallisneria plants (per m2) across all samples, including experimental and lake-wide study sites. The blue line represents the average annual hydroperiod from 1993 to 2002 for each depth bin.
106
Discussion
Generally, lakes with highly productive, stable environments promote high
biomass, broad-leaf species with slow generation times and the capacity for vegetative
spread (Day et al. 1988, Wisheu and Keddy 1992). These communities are typically
dominated by a few competitive species and have lower diversity littoral zones, quite
similar to the Pontederia-dominated shoreline that occurred on Lake Toho prior to
treatment. Lake drawdowns in Florida are generally performed to allow germination and
expansion of desirable grassy species into these mono-cultural habitats, which is
important to their persistence under stabilized water levels (Moyer et al. 1989). After
the treatment and reflooding of Lake Toho that took place in late summer of 2004, there
was substantial colonization of several grassy and ruderal species in scraped areas,
including P. acuminatum, P. geminatum, and Eleocharis spp. However, other species
typically associated with the pre-treatment, degraded conditions were also present,
including Hydrilla, Pontederia, Alternanthera, and Polygonum.
The hurricanes and associated high water essentially removed the earliest
colonizers; there was an average of only 3 g of dry biomass and 40 g of wet biomass
collected across entire scraped study sites the following growing season (June 2005).
The species described as early colonizers were typically small, newly sprouted
individuals that had low biomass and higher densities, though there was still an
additional 80% biomass reduction in all scraped areas less than a year after the
hurricanes passed. All of the first colonizing species were reduced in abundance or
eliminated entirely within that period. However, those same species were found again
at greater abundances later in the study period, with the exception of one;
P. acuminatum. This species had the highest initial biomass of those found in the lake-
107
wide study sites, and a density of roughly 60 plants per square meter. After the
hurricanes that density was reduced to 9 per square meter, and it was rarely collected
from those sites after.
This species was also found in the experimental plots, but infrequently and with
low abundance relative to common species. There was no increase in densities or
biomass in treated plots like there was in the lake-wide studies, but its biomass was still
reduced after the hurricanes. However, it was found later in both control and treated
plots at the same low same low frequency and abundance that it had prior to treatment.
This indicates that the increases recorded in the lake-wide sites were somewhat of a
patchy event, and indeed occurred in only three of the five sites. At least one other
study documented an increase in P. acuminatum following low water events in Florida
lakes (Havens 2005), but this is generally not a dominant shoreline species in the
region. Several local wetland flora books and regional plant I.D. websites do not list the
species, further suggesting its local infrequency.
While it is unknown whether this species could have remained at least locally
abundant in shallow, scraped sections of shoreline if the hurricanes had not passed, it
seems probable that other regionally dominant species, specifically invasive exotic
grasses like P. repens, would have replaced it. By the end of the study P. repens
dominated all scraped plots in both the experimental and lake-wide study areas. This
species typically colonizes disturbed sites and is very problematic in many of Florida's
water bodies, having displaced thousands of acres of native marsh in other systems
following droughts or low water events (Smith et al. 2004). Given the potential for P.
repens to invade and persist in disturbed areas, as well as the fact it has been common
108
on Lake Toho since the earliest vegetation studies (Sincock et al. 1957, Holcomb and
Wegener 1971, Moyer et al. 1989), it seems unlikely that P. acuminatum, a relatively
infrequent species in the region would have remained abundant for long.
One of the biggest impacts of the hurricanes may have taken place at depths
beyond where scraping took place, where P. geminatum was the most common and
abundant species. Like most grasses, this species germinates during low water periods
(Johnson et al. 2007.) and is typically found on Toho and other regional lakes at depths
concurrent with previous drawdowns. It was predicted that P. geminatum would expand
shoreward after organic substrates and dense competitors were removed (see
http://aquat1.ifas.ufl.edu/guide/laketoho.html for project details), and P. geminatum was
one of the few species to substantially increase in biomass immediately after the
treatment (primarily in deeper, unscraped areas). It was also one of the early colonizers
of treated shorelines and one of the first to recover following hurricane damage.
However, the biomass increase from germination in deeper areas was immediately lost
after the hurricanes, presumably because the dense, new growth could not withstand
the high winds or water levels. Visual observations following the hurricanes confirmed
the biomass reductions shown in the samples, as most shorelines had P. geminatum
wrack deposited at the high water line.
Even after a nearly 50% reduction in biomass, P. geminatum abundance was still
well within pre-treatment levels directly after the hurricanes and throughout the
remainder of the study. There likely would have been much higher densities and
possibly an expansion into previously uninhabited areas if the newly germinated plants
could have survived rising water levels. For example, most of the lily pad communities
109
(Nuphar advena and Nymphaea odorata) were largely eliminated from the scraped and
deeper water sections of shoreline, presumably due to desiccation and rapid water level
increases (Ch. 2). It seems reasonable that the dry down expansion of P. geminatum
into those areas previously occupied by dense floating leaf communities could have
remained for some time.
Overall, the initial composition of early site colonizers did not appear to change
much after the hurricanes. Early growth was severely limited due to high water, but the
initially dominant species all recovered biomass after successive years of normal lake
stages. The compositions found after nearly four years of post-treatment succession
did not begin to take form until after the pre-hurricane colonizers had recovered. For
example, P. geminatum, Pontederia, Eleocharis, Hydrilla, Polygonum, and
Alternanthera were all dominant species initially, and were again dominant two growing
seasons after the hurricanes passed (June 2006). Beginning in December of 2006,
Vallisneria and P. repens became increasingly dominant. In other words, the ‘final’
composition documented at the end of the study formed after the initial colonizers were
already in place.
It seems reasonable that if water levels had followed normal lake regulation
schedules after the treatment, the same pattern of site colonization would have taken
place, but most likely a year or two sooner. There most likely would have been more P.
geminatum, particularly in the deeper unscraped areas, but given that fierce competitors
like Pontederia and P. repens were among the early colonizers of scraped areas, it
seems that the same succession pattern would have taken place at a more rapid pace.
These were the results in a previous, small-scale muck removal on Lake Toho, where
110
within two years of treatment Pontederia, Alternanthera, Hydrilla, P. repens and
Eleocharis were again among the most dominant species (Moyer et al. 1989).
These results also fit wetland community succession models, where, following
drawdowns, perennial communities rapidly reestablish once original water levels are
returned (Seabloom et al. 2001). Conversely, this rate of establishment has been linked
to the level of flooding (deviation from normal) during the recovery period. If the normal
annual lake stages had been restored immediately following restoration, it seems likely
that the previously dominant species would have had the advantage.
The succession studies and models predicting rapid recovery assume adequate
propagule availability, however, and this may not be the case in this study. When
original communities fail to reestablish, dispersal capabilities or propagule availability
are typically a limiting factor (Ellison and Bedford 1995), or conditions may have
changed such that the original cohorts can no longer persist at the site (Turner et al.
1998). The restoration project on Lake Toho probably falls somewhere in between
these two scenarios, as sediment characteristics were altered, water depths were
slightly increased, and the seedbank was at least severely disturbed, if not relocated
entirely. However, half of the sediment and/or vegetation that were removed form the
shoreline was deposited back into the shallow littoral zone on spoil islands, and only
about half of the emergent littoral zone was scraped (the shallower half, 45–135 cm).
While seed availability and vegetative regeneration were surely limited following the
treatment, it seems reasonable that all of the original species were still within dispersal
range of the scraped sites. Given that adult plants were removed, initial succession
would most likely have been driven by germination and dispersal limitations instead of
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clonal or rhizomatous spreading. However, the close proximity of available propagules,
similar species pool, and the inevitable return of stable hydrologic conditions will most
likely favor reestablishment of the original communities eventually.
The major surprise in this project was the invasion and at least short-term
persistence of a previously rare species on Lake Toho, Vallisneria. This submersed
species rapidly expanded in areas of another regional lake (Okeechobee) following low
water periods, and apparently is capable of displacing some submersed species under
the right conditions (Havens et al. 2004). Vallisneria and most other species did not
rapidly expand until unusually low winter water levels in 2006, after which the current
dominant species increased dramatically. This may have been due to high turbidity and
low water quality that persisted in the lake for up to two years following the hurricanes
(Hoyer et al. 2008), presumably from flushing surrounding agricultural lands and a
massive decline in macrophyte abundance after the treatment. While Vallisneria is fairly
tolerant of low light conditions, it has higher light requirements for early growth than it
does for germination (Kimber et al. 1995). It is possible that extended low winter water
levels during 2006 aided in the expansion of Vallisneria from deeper water, unscraped
habitats.
The communities found after four years of succession were likely a result of recent
hydrological conditions, as well as dispersal capabilities. Two of the top four species
were invasive exotics, apparently displacing slower growing, broad leaf emergents like
Pontederia for the time being. However, the dominance of submersed species, both
Vallisneria and Hydrilla in scraped areas, is likely due to higher water levels in general
following the treatment. More than half of the areas occupied by Vallisneria have an
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annual hydroperiod < 95% under current lake regulations, elevations typically occupied
by emergent species. Had water levels been held below maximum or at minimum lake
stage for a full growing season after the restoration, there likely would have been much
less submersed species and a more rapid expansion of aggressive emergents, like
Pontederia and P. repens. While prolonged high water and increased turbidity from the
hurricanes undoubtedly affected early colonizers, the communities found at the end of
this study seemed to be a result of several growing season hydrologies. Keeping water
levels lower for a full growing season after the enhancement project likely would have
promoted more P. geminatum in scraped areas, but substantially less Vallisneria. As
many studies have shown, the hydrologic regime during colonization/germination of
wetland soils will has a large impact on initial community composition (van der Valk
1981, Seabloom et al. 1998), but ultimately species distributions will be based on
flooding tolerances (Squires and van der Valk 1992). Without changes to annual lake
schedules, the communities that succeed after such large-scale lake restoration
projects will likely be very similar to pre-treatment compositions once initial dispersal
limitations are overcome.
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CHAPTER 5 DISCUSSION
Review
This study was the most thorough documentation of littoral vegetation responses
to mechanical muck removal, particularly on this scale of application. Previous studies
monitored short-term (two years) changes in species frequencies in scraped areas after
treatment (Moyer et al. 1989), but this paper details vegetation changes over a longer
time frame (four years), includes pre-treatment descriptions, and monitors shifts in
distributions along a water depth gradient.
The overall success of this restoration project was mixed, in that specified
compositions were not achieved, but desired habitat characteristics were. The FFWCC
predicted that over time healthy stands of knotgrasses (more commonly known as P.
geminatum), bulrushes (Scirpus californicus), and eelgrass (Vallisneria), among other
‘desirable species’, would rebound from the seedbanks as workers managed against
problematic species (http://aquat1.ifas.ufl.edu/guide/laketoho.html).
The primary community, or “problematic species” targeted by the restoration was
Pontederia, which I found dominated in roughly 30–122 cm in water depth prior to
treatment, with Alternanthera identified as another strong indicator for this community.
Shoreward of this group was a mixture of Luziola, P. repens, and Eleocharis, all of
which have been found at varying frequencies since the 1950’s (Sincock et al. 1957,
Holcomb and Wegener 1971, Moyer et al. 1989).
The deepest water edge of the Pontederia/Alternanthera community was bordered
by occasional floating mats, including Hydrocotyle, Lymnobium, and Eichhornia,
indicating an abrupt shift from dense emergent communities to deeper-water habitats.
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These were the communities believed to form an organic, floating barrier to fish
attempting to access shallow spawning areas (Moyer et al. 1989). Based on a 10 yr
period of stage records (1993–2002) the lakeward extent of the dominant Pontederia
zone extended just beyond the annual minimum water depths.
Typha stands were scattered along the deepest edge of this community, as
cattails generally benefit from several centimeters of flooding for germination, but not
complete exposure during annual lows (Johnson et al. 2007). Beyond the 100%
hydroperiod zone there were water lily communities, primarily Nuphar and Nymphaea,
while Hydrilla and P. geminatum dominated the deepest portions of the emergent littoral
zone.
Soil organic content was highly variable before lake restoration, ranging anywhere
from 2% to 96% in the top 10 cm of substrate, with a mean of 33% across plots and a
median of only 11%. These numbers dropped to barely detectable levels four years
after treatment (< 2%), but were even significantly reduced in control plots (mean 15%,
median 4%). While peat depths were not actually measured, the soil corer generally
reached a sand or silt substrate underneath the organic layer while sampling, which
often occurred before 10 cm and made core retrieval more difficult. There were few
instances where the amount of peat or organic material exceeded 10 cm, though
samples from a cove and floating mat exceeded 20 cm on a few occasions.
Overall, the objective of removing existing plant monocultures and associated
organic material was achieved, though there was only a slight rise in the effective
number of species in scraped areas after restoration (5.3 to 6.2). However, given the
loss of water lily communities from deeper, unscraped areas, the total effective species
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for the emergent littoral zone dropped from 7.9 to 5.5 after restoration. It is unclear
what role the hurricanes may have played in eliminating deeper water Typha and water
lily communities.
The dense Pontederia community was primarily replaced by P. repens in the
shallowest sections of shoreline (< 98 cm), and by Vallisneria in the deeper areas.
Historically, P. repens was the most frequently occurring species along study transects,
occupying nearly the same elevations Pontederia did due to greater shoreline
fluctuations (Sincock et al. 1957). However, Vallisneria was very infrequent in early
studies, and Lake Toho was described as having too low an alkalinity to support much
submersed vegetation (Sincock et al. 1957).
While the replacement of Pontederia with P. repens in shallow water does more
closely resemble pre-regulation (historic?) shorelines, the expansion of Vallisneria was
unprecedented in this system. Havens et al. (2004) documented a recovery of
Vallisneria following low water on Lake Okeechobee, but this presumably occurred from
existing seedbanks and was accompanied by a rebound of Potomageton and Hydrilla
as well. The seedbank was largely removed or at least severely disturbed on Toho
following muck removal, and Vallisneria was rarely seen prior to treatment (Moyer et al.
1989), indicating a possible rapid expansion from isolated, deeper-water patches. This
suggests that while Vallisneria remained on the lake for over 50 years, it was apparently
a poor competitor under both historic and pre-treatment conditions, never being more
than infrequently recorded. The question is, was establishment the only factor limiting
its distribution, and can it continue to occupy large areas under the same environmental
conditions and species associations as before?
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P. geminatum was predicted to be the major benefactor of this restoration,
including expansion into areas previously occupied by Pontederia
(http://aquat1.ifas.ufl.edu/guide/laketoho.html). This species began establishing in
scraped areas immediately after muck removal but was reduced in abundance following
major hurricanes in 2004. There were substantial increases in deeper-water
P. geminatum communities from the drawdown as well, but those gains were also lost
during the hurricanes.
While water levels during initial colonization undoubtedly affected establishment
rates and compositions, P. geminatum was still one of the few species present in
scraped areas even a year after the hurricanes passed. While never dominant,
P. geminatum remained one of the top five species in terms of total biomass in treated
areas at the end of the study. This suggests that while P. geminatum was inhibited by
the rapid water rise and prolonged flooding from the hurricanes, it faired better than
other colonizing species and still was unable to dominate the scraped areas as
predicted.
Overall, the short-term responses of this restoration were that the dense, robust
communities that dominated the shallow littoral zone for over 20 years were replaced
primarily with Vallisneria, an important species for waterfowl (McAtee 1939, Sculthorpe
1967) and sportfish (Barnett and Schneider 1974), and which permits better recreational
access to restored areas. Whether Vallisneria can remain dominate at these depths
and/or at what cost is unknown, as half of the zone occupied by this submersed aquatic
was exposed annually from 1993 to 2002, and the invasive exotic Hydrilla is known to
displace this species in fertile environments (Van et al. 1999). Hydrilla biomass
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increased 58% after the restoration, and though this was primarily in deeper areas than
where Vallisneria occurred, it still suggests the potential for invading scraped areas
without continual intervention. As such, the Vallisneria community is likely to be
compressed from emergent competition in areas with < 100% hydroperiod, and from
Hydrilla and possibly recovering water lily communities at the deeper end of its gradient.
Management Implications
The muck removal treatment applied to Lake Toho was the largest and most
intensive removal event to date, and was used as a substitute for the loss of historic
flood/drought cycles that would have naturally flushed/oxidized accumulated organic
materials or floating mats during such events. This unique approach was an attempt to
reset decades of succession by removing the species, seedbanks, and soils associated
with degraded shorelines. Recolonization was regulated with selective herbicide
applications in an effort to force historical patterns on the sandy, exposed shorelines
without the historical processes that maintained the system originally. After four years
of post-treatment monitoring, these efforts appeared to have mixed results.
While the objective of establishing sparse emergent habitat was not realized, the
communities that developed along the treated shorelines did have similar desirable
attributes as the target habitat. Organic soils were replaced with sandy substrates, the
submersed communities that were established provide important habitat for fish (Barnett
and Schneider 1974) and waterfowl (McAtee 1939, Sculthorpe 1967), and the removal
of floating mats and dense emergent vegetation allowed for better recreational access.
When system degradation cannot be reversed at an acceptable cost, managers should
strive for the biotic structure and ecosystem services desired by stakeholders, while
promoting communities that are both feasible and resilient (Seastedt et al. 2008). This
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project did accomplish the former, but the resilience or longer-term establishment of a
submersed community at these lake elevations is doubtful. A regional drought could
expose most of the shoreline occupied by the newly established submersed community,
which would allow rapid invasion by emergent species like Pontederia, and especially P.
repens (Smith et al. 2004). Without substantial changes in water regulation schedules,
it is likely that Pontederia will continue to expand lakeward from its narrow bands along
the shore, as happened from 1979 to 1987 (Moyer et al. 1989).
The importance of hydrological conditions to wetland control and structure is
widely recognized (National Research Council 1996), and restoration of these systems
must begin with hydrology (Hunt 1999). The communities established on Lake Toho
following restoration may be dependent on constant herbicide applications, which are
increasingly regulated and dependent on currently declining state budgets (BIMP
2004). While restoring the variability of the natural hydrological regime is not possible in
this or many other aquatic systems, it is possible that partial improvements to
hydroperiods could be of value (Zedler 2000). For example, Lake Toho is consistently
held between 15.9 and 16.8 meters NGVD annually, with little to no inter-annual
variability. Year to year fluctuations are known to increase plant diversity, and can
essentially double the number of vegetation types on a shoreline (Keddy and Fraser
2000). Managing lake levels with 0.5 m of inter-annual variation, for example, may
reduce the amount of herbicides needed to keep robust, resilient communities from
dominating the zone of intra-annual variation.
Ecosystem restoration will likely become increasingly complex as more systems
are exposed to novel conditions, but should continue to focus on key structuring
119
processes and promoting desired ecosystem functions under future conditions. Even
as recent studies have called for accepting new communities instead of historical states
(Seastedt et al. 2008) and promoting new approaches to managing under novel
conditions (Holling 2001), the basic premise of successful restoration attempts should
not be abandoned. Restoring or at least partially implementing key structuring
processes (Landres et al. 1999) should remain at the forefront of pattern restoration,
and will minimize external efforts and costs (Mitsch and Wilson 1996). Hydrologic
regimes will become increasingly difficult to restore with population growth and
changing climates, and with it the temptation to maintain pattern with herbicides,
species removals, and bulldozers, instead of water level manipulation.
Before applying the results of this project to other large, shallow lakes where muck
removal is being considered, several caveats should be addressed. Lake Toho has a
significant distribution of Hydrilla populations in deeper areas of the littoral zone, beyond
the depths sampled in this study. Without submersed species stabilizing deeper
sediments, drawdowns might increase wind-induced turbulence of the lake bottom;
releasing nutrients, decreasing water clarity, and perhaps limiting macrophyte
establishment even upon reflooding (Blindow et al 1993). If a large lake already has
unconsolidated sediments and deep-water portions unsupportive of submersed
vegetation, low water levels and the removal of shoreline vegetation may cause a shift
to a phytoplankton-dominated state (Scheffer et al. 1993).
Lake Toho had the lowest amount of submersed vegetation since the 1980’s
(BIPM 2005) immediately following this restoration, and lower water quality measures
for nearly two years. These changes were attributed to tropical disturbances during the
120
reflooding phase of treatment, which is another important consideration when applying
large-scale habitat modifications. Several conditions will likely affect the outcome of
mechanical muck removal projects, including lake size, water depth, maximum fetch,
nutrient concentrations, and sediment stability, any of which may affect water
quality/turbidity and subsequent vegetation establishment in treated areas.
Finally, water levels after treatment should be a major focus in these restoration
efforts, as they are instrumental in influencing seed viability (Poiani and Johnson 1989),
recruitment (Seabloom et al. 1998), and the growth and survival of adult plants (Squires
and van der Valk 1992) on the scraped shorelines. The hurricanes that occurred during
this study resulted in a rapid increase of water levels that were held at maximum pool
for nearly seven months. Had water returned at a slower rate or oscillated during the
early recovery period, different communities may have been established (van der Valk
1981, Weiher et al. 1996).
Longer-term monitoring is recommended after such projects, as the treated areas
were only beginning to stabilize by the end of this study. Several of the dominant
species were still consistently increasing in biomass over the last few samples,
including the target species Pontederia and its large-scale replacements, P. repens and
Vallisneria. There is still valuable information about the long-term persistence of
establishing communities or recovery of undesirable communities that has not yet been
collected. Without adequate monitoring of management efforts, it will be impossible to
learn from their long-term effects.
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APPENDIX A SPECIES LIST
Table A. Common species sampled over the period of study. Species
Code Scientific Name Common Name
ALTPH Alternanthera philoxeroides Alligator weed
BACCA Bacopa caroliniana Lemon Bacopa BIDLA Bidens laevis Burrmarigold BRAMU Bracharia mutica Para grass CENAS Centella asiatica Coinwort CERAT Ceratophyllum spp. Coontail CHASP Chara spp. Musk grasses CYPSP Cyperus spp. Sedges DIOVI Diodia virginiana Buttonweed EICCR Eichornia crassipes Water hyacinth ELESP Eleocharis spp. Spikerushes HABRE Habenera repens Water-spider orchid HYDSP Hydrocotyle spp. Pennywort HYDVE Hydrilla verticillata Hydrilla LEESP Leersia spp. Cut grasses LUDAR Ludwigia arcuata Piedmont primrose LUDSP Ludwigia spp. Ludwigia/Water Primrose LUZFL Luziola fluitans Water grass LYMSP Lymnobium spongia Frog's bit NAJGU Najas guadalupensis Southern naiad NELLU Nelumbo lutea Water lotus NITSP Nitella spp. Stoneworts NUPLU Nuphar advena Spatterdock NYMAQ Nymphoides aquatica Banana lily NYMOD Nymphaea odorata Fragrant water lily PANHE Panicum hemitomon Maidencane PANRE Panicum repens Torpedo grass
PASGE Paspalidium geminatum Egyptian paspalidium (commonly knot grass or Kissimmee grass)
PASAC Paspalum acuminatum Canoe grass POLDE Polygonum densiflorum Smartweed
POLHY Polygonum hydropiperoides Wild water-pepper
PONCO Pontederia cordata Pickerel weed RHYNSP Rhyncospora spp Beakrushes SAGLN Sagittaria lancifolia Duck potato SAGLT Sagittaria lattifolia Arrowhead
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Table A. continued.
Species Code Scientific Name Common Name
SCICA Scirpus californicus Giant bulrush SCICU Scirpus cubensis Bulrush SESPU Sesbania punicea Purple Sesban TYPSP Typha spp. Cattails UTRSP Utricularia spp. Bladderworts VALAM Vallisneria americana Eelgrass
Nomenclature follows that of Tobe et al. 1998.
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BIOGRAPHICAL SKETCH
Zach Welch began his college education at the University of Florida in 1994,
coming from the small-town high school of Dunnellon, FL. Like most, he struggled to
find an interest in the first year or two of undergraduate coursework, but was
immediately hooked upon taking an introductory wetland ecology class, taught by Dr.
Peter Frederick. He earned a Bachelor’s degree in 1999 majoring in Wildlife Ecology
and Conservation, and then began working for Dr. Kitchens at the Florida Cooperative
Fish and Wildlife Research Unit.
He started as a research assistant in the summer of 2000, eventually earning his
Master’s degree in 2004 in Wildlife Ecology and Conservation. Having thoroughly
enjoyed his experience with Dr. Kitchens and the Cooperative Research Unit, he
eagerly started his PhD program with the same advisor, this time majoring in
Interdisciplinary Ecology to allow greater emphasis on wetland studies. Throughout his
graduate career, wetland ecology and vegetation modeling were among his favorite
study topics, and he earned his Doctoral degree in the fall of 2009 after a long and
gratifying experience.